.....Instruction ManualA
RT
Dri
veG
General-Purpose Inverter230/400/460V Class
575V Class
ARTDriveG -EV
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Keep the manual in a safe place and available to engineering and installation personnel during the product functioning period.
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The data can only be used for the product description and they can not be understood as legally stated properties.
This manual is updated according to firmware version V03.04.
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ARTDriveG Instruction Manual Table of Contents • 3
Table of Contents
Safety Symbol Legend - Precautions de securité...................................................................... 6
Chapter 1 - Safety Precautions .................................................................................................. 7
1.1 Power Supply and Grounding ........................................................................................................................................................ 10
Chapter 2 - General ................................................................................................................... 11Features ............................................................................................................................................................................................ 12
Accessories / Options ........................................................................................................................................................................ 12
Chapter 3 - Inspection Procedure, Component Identification and Standard Specification .... 13
3.1 Upon Delivery Inspection Procedures ............................................................................................................................................ 13
3.1.1 General ..................................................................................................................................................................................... 13
3.1.2 Inverter Type Designation .......................................................................................................................................................... 13
3.1.3 Nameplate ................................................................................................................................................................................ 14
3.2 Component Identification .............................................................................................................................................................. 15
3.3 Standard Specifications ................................................................................................................................................................ 16
3.3.1 Permissible Environmental Conditions ....................................................................................................................................... 16
Disposal of the Device ............................................................................................................................................................... 17
3.3.2 Mains Connection and Inverter Output ....................................................................................................................................... 17
3.3.3 AC Input Current ........................................................................................................................................................................ 20
3.3.4 AC Output .................................................................................................................................................................................. 20
3.3.5 Open-Loop and Closed-Loop Control Section .............................................................................................................................. 21
3.3.6 Accuracy .................................................................................................................................................................................. 21
Chapter 4 - Installation Guidelines ........................................................................................... 23
4.1 Mechanical Specification .............................................................................................................................................................. 23
4.2 Watts Loss, Heat Dissipation, Internal Fans and Minimum Cabinet Opening Suggested for the Cooling ........................................ 27
4.2.1 Cooling Fans Power Supply ....................................................................................................................................................... 28
4.3 Installation Mounting Clearance.................................................................................................................................................... 29
4.4 Motors and Encoder ...................................................................................................................................................................... 30
4.4.1 AC Induction Motors .................................................................................................................................................................. 30
4.4.2 Encoder .................................................................................................................................................................................... 31
Chapter 5 - Wiring Procedure................................................................................................... 33
5.1 Accessing to the Connectors ........................................................................................................................................................ 33
5.2 Power Section .............................................................................................................................................................................. 35
5.2.1 Maximum Cable Cross Section for Power Terminals .................................................................................................................. 36
5.2.2 Rectification and Intermediate (D.C.) Circuit .............................................................................................................................. 37
5.2.3 Inverter ..................................................................................................................................................................................... 38
5.3 Regulation Section ........................................................................................................................................................................ 39
5.3.1 R-AGy Regulation Card .............................................................................................................................................................. 39
5.3.2 Terminal Assignments on Regulation Section ............................................................................................................................. 40
5.4 Serial Interface ............................................................................................................................................................................. 41
5.4.1 In General ................................................................................................................................................................................. 41
5.4.2 RS 485 Serial Interface Connector Description ........................................................................................................................... 42
5.5 Typical Connection Diagrams ........................................................................................................................................................ 43
5.5.1 AGy Connection ........................................................................................................................................................................ 43
5.5.2 Engineering Notes ..................................................................................................................................................................... 44
5.5.3. Parallel Connection on the AC (Input) and DC (Intermediate Circuit) Side of Several Inverters ................................................... 45
5.6 Circuit Protection .......................................................................................................................................................................... 46
5.6.1 External Fuses of the Power Section .......................................................................................................................................... 46
5.6.2 External Fuses of the Power Section DC Input Side .................................................................................................................... 47
5.6.3 Internal Fuses ............................................................................................................................................................................ 48
5.7 Chokes / Filters (Optional) ............................................................................................................................................................ 48
5.7.1 AC Input Chokes ........................................................................................................................................................................ 49
5.7.2 Output Chokes ........................................................................................................................................................................... 49
4 • Table of Contents ARTDriveG Instruction Manual
5.7.3 Interference Suppression Filters ................................................................................................................................................ 50
5.7.3.1 EMI filter connections for Sizes 1007...3150 (230V...480V) .............................................................................................. 52
5.7.3.2 EMI filter connections for Sizes 4185...82000 (230V...480V) ............................................................................................. 53
5.8 Braking in the AGy System ........................................................................................................................................................... 54
5.8.1 Braking Unit .............................................................................................................................................................................. 54
5.8.1.1 External Braking Resistor ............................................................................................................................................... 56
5.8.2 D.C. Braking .............................................................................................................................................................................. 59
5.9 Discharge Time of the DC-Link ..................................................................................................................................................... 59
Chapter 6 - Drive Keypad Operation......................................................................................... 60
6.1 Keypad ......................................................................................................................................................................................... 60
6.2 Language Selection ....................................................................................................................................................................... 61
6.3 Updating the language in E@syDrives .......................................................................................................................................... 61
6.4 Moving Through the Drive Main Menu .......................................................................................................................................... 62
6.5 Scrolling Through the Drive Parameters ........................................................................................................................................ 63
6.6 Parameters Modification .............................................................................................................................................................. 63
6.7 Quickstart procedure .................................................................................................................................................................... 64
Basic settings for trial run ................................................................................................................................................................... 64
Standard settings ............................................................................................................................................................................... 64
Advanced settings ............................................................................................................................................................................. 66
Chapter 7 - Parameter Description .......................................................................................... 67
7.1 Parameters List ............................................................................................................................................................................ 67
7.2 Menu d - DISPLAY ....................................................................................................................................................................... 96
Basic ................................................................................................................................................................................................. 96
Overload ............................................................................................................................................................................................ 97
Inputs/Outputs .................................................................................................................................................................................... 98
Encoder ........................................................................................................................................................................................... 101
Option .............................................................................................................................................................................................. 102
Pid .................................................................................................................................................................................................. 102
Alarm list ......................................................................................................................................................................................... 103
Drive Identification ........................................................................................................................................................................... 103
Utility ............................................................................................................................................................................................... 104
7.3 Menu S - START-UP .................................................................................................................................................................... 105
Power Supply .................................................................................................................................................................................. 105
V/F Characteristic ........................................................................................................................................................................... 105
Motor Data ...................................................................................................................................................................................... 106
Commands & Referencies ................................................................................................................................................................ 107
Functions ......................................................................................................................................................................................... 109
Utility ............................................................................................................................................................................................... 110
7.4 Menu I - INTERFACE ................................................................................................................................................................... 111
Digital Inputs Regulation Board ........................................................................................................................................................ 111
Digital Inputs Expansion Board ......................................................................................................................................................... 112
Programmable Logic Output ............................................................................................................................................................. 113
Digital Ouputs Regulation Board ....................................................................................................................................................... 113
Digital Outputs Expansion Board ....................................................................................................................................................... 115
Analog Inputs Regulation Board ....................................................................................................................................................... 116
Analog Outputs Regulation Board ..................................................................................................................................................... 120
Analog Outputs Exp Board ................................................................................................................................................................ 123
Enabling Virtual I/O .......................................................................................................................................................................... 124
Encoder Configuration ...................................................................................................................................................................... 129
Serial Configuration ......................................................................................................................................................................... 130
Options Configuration ....................................................................................................................................................................... 132
SBI Configuration ............................................................................................................................................................................. 133
7.5 Menu F - FREQ & RAMPS ........................................................................................................................................................... 135
Motorpotentiometer ......................................................................................................................................................................... 135
Reference Limits .............................................................................................................................................................................. 137
Reference Sources .......................................................................................................................................................................... 138
Multispeed Function ........................................................................................................................................................................ 139
ARTDriveG Instruction Manual Table of Contents • 5
Ramp Configuration ......................................................................................................................................................................... 141
Jump Frequencies ........................................................................................................................................................................... 143
7.6 Menu P - PARAMETERS.............................................................................................................................................................. 145
Commands ...................................................................................................................................................................................... 145
Control Mode .................................................................................................................................................................................. 150
Power Supply .................................................................................................................................................................................. 151
Motor Data ...................................................................................................................................................................................... 151
V/F Curve ........................................................................................................................................................................................ 152
Ouput Frequency Limit ..................................................................................................................................................................... 154
Slip Compensation ........................................................................................................................................................................... 154
Boost ............................................................................................................................................................................................... 155
Automatic Flux Regulation ................................................................................................................................................................ 156
Anti Oscillation Function .................................................................................................................................................................. 156
Closed Loop Speed Control .............................................................................................................................................................. 156
SW Current Clamp ........................................................................................................................................................................... 158
Current Limit .................................................................................................................................................................................... 159
DC Link Limit .................................................................................................................................................................................... 161
Over Torque Alarm Configuration ...................................................................................................................................................... 162
Motor Overload Configuration .......................................................................................................................................................... 163
BU Configuration .............................................................................................................................................................................. 163
DC Brake Configuration .................................................................................................................................................................... 164
Autocapture function ........................................................................................................................................................................ 165
Undervoltage Configuration .............................................................................................................................................................. 167
Overvoltage Configuration ................................................................................................................................................................ 171
Autoreset Configuration .................................................................................................................................................................... 172
External Fault Configuration ............................................................................................................................................................. 173
Phase Loss Detection ....................................................................................................................................................................... 173
Voltage Reduction Configuration ...................................................................................................................................................... 174
Frequency Threshold ....................................................................................................................................................................... 175
Steady State Signalling .................................................................................................................................................................... 177
Heatsink Temperature Threshold ....................................................................................................................................................... 177
PWM Setting ................................................................................................................................................................................... 178
Dead Time Compensation ................................................................................................................................................................. 179
Display Setting ................................................................................................................................................................................ 179
Protection ........................................................................................................................................................................................ 180
7.7 Menu A - APPLICATION ............................................................................................................................................................. 181
PID Setting ...................................................................................................................................................................................... 181
PID Gains ......................................................................................................................................................................................... 185
PID Limits ........................................................................................................................................................................................ 185
Programmable Logic Inputs ............................................................................................................................................................. 188
7.8 Menu C - COMMANDS ............................................................................................................................................................... 190
Basic ............................................................................................................................................................................................... 190
Alarm Register Reset ....................................................................................................................................................................... 190
External Key .................................................................................................................................................................................... 191
LCD keypad ..................................................................................................................................................................................... 191
Tuning ............................................................................................................................................................................................. 191
7.9 Menu H - HIDDEN ...................................................................................................................................................................... 192
Virtual I/O Commands ...................................................................................................................................................................... 192
Profidrive Parameters ...................................................................................................................................................................... 193
Drive Status ..................................................................................................................................................................................... 194
Parameters Reading Extension ......................................................................................................................................................... 194
Remote I/Os Control ......................................................................................................................................................................... 195
Serial Link Commands ...................................................................................................................................................................... 195
Chapter 8 - Serial Protocol ..................................................................................................... 197
8.1 Modbus RTU Protocol for AGy drives ........................................................................................................................................... 197
8.1.1 Introduction ............................................................................................................................................................................. 197
8.1.2 The MODBUS Protocol ............................................................................................................................................................ 197
8.1.3 Message format ...................................................................................................................................................................... 197
8.1.3.1 The address ................................................................................................................................................................... 197
8.1.3.2 The function code ........................................................................................................................................................... 197
6 • Table of Contents ARTDriveG Instruction Manual
Safety Symbol Legend - Precautions de securité
Indicates a procedure, condition, or statement that, if not strictly observed, could result in perso-nal injury or death.
Indique le mode d'utilisation, la procédure et la condition d'exploitation. Si ces consignes ne sont passtrictement respectées, il y a des risques de blessures corporelles ou de mort.
Indicates a procedure, condition, or statement that, if not strictly observed, could result in damageto or destruction of equipment.
Indique et le mode d'utilisation, la procédure et la condition d'exploitation. Si ces consignes ne sont passtrictement respectées, il y a des risques de détérioration ou de destruction des appareils
Indicates a procedure, condition, or statement that should be strictly followed in order to optimizethese applications.
Indique le mode d'utilisation, la procédure et la condition d'exploitation. Ces consignes doivent êtrerigoureusement respectées pour optimiser ces applications..
Warning!
Caution
Attention
NOTE! Indicates an essential or important procedure, condition, or statement.
Indique un mode d'utilisation, de procédure et de condition d'exploitation essentiels ou importants
8.1.3.3 CRC16 ............................................................................................................................................................................ 198
8.1.3.4 Message synchronization .............................................................................................................................................. 198
8.1.3.5 Serial line setting ........................................................................................................................................................... 198
8.1.4 Modbus functions for the drive ................................................................................................................................................ 199
8.1.4.1 Read Output Registers (03) ............................................................................................................................................ 199
8.1.4.2 Read Input Registers (04) .............................................................................................................................................. 199
8.1.4.3 Preset Single Register (06) ............................................................................................................................................ 200
8.1.4.4 Read Status (07) ............................................................................................................................................................ 200
8.1.4.5 Preset Multiple Registers (16) ....................................................................................................................................... 201
8.1.5 Error management ................................................................................................................................................................... 201
8.1.5.1 Exception codes ............................................................................................................................................................ 202
8.1.6 System configuration ............................................................................................................................................................... 202
8.2 Proprietary protocol ..................................................................................................................................................................... 203
8.2.1 Introduction ............................................................................................................................................................................. 203
8.2.2 Message format ...................................................................................................................................................................... 203
8.2.3 Address ................................................................................................................................................................................... 204
8.2.4 Control code ........................................................................................................................................................................... 204
8.2.5 Functions ................................................................................................................................................................................ 204
8.2.6 Msg Slave meaning ................................................................................................................................................................ 205
Chapter 9 - Troubleshooting ................................................................................................... 207
9.1 Drive Alarm Condition .................................................................................................................................................................. 207
9.2 Alarm Reset ................................................................................................................................................................................. 207
9.3 List of Drive Alarm Events ........................................................................................................................................................... 208
9.4 Kbg fw mismatch ........................................................................................................................................................................ 208
Chapter 10 - EMC Directive, Declarations of EC-Conformity ................................................ 209
Index Parameters ................................................................................................................... 212
ARTDriveG Instruction manual Chapter 1 - Safety • 7
Chapter 1 - Safety Precautions
According to the EEC standards the ARTDRiveG and accessories must be used only after checkingthat the machine has been produced using those safety devices required by the 89/392/EEC setof rules, as far as the machine industry is concerned. These standards do not apply in the Americas,but may need to be considered in equipment being shipped to Europe.Drive systems cause mechanical motion. It is the responsibility of the user to insure that anysuch motion does not result in an unsafe condition. Factory provided interlocks and operatinglimits should not be bypassed or modified.Selon les normes EEC, les drives ARTDRiveG et leurs accessoires doivent être employés seulementaprès avoir verifié que la machine ait été produit avec les même dispositifs de sécurité demandés par laréglementation 89/392/EEC concernant le secteur de l’industrie.Les systèmes provoquent des mouvements mécaniques. L’utilisateur est responsable de la sécuritéconcernant les mouvements mécaniques. Les dispositifs de sécurité prévues par l’usine et les limitationsoperationelles ne doivent être dépassés ou modifiés.
Electrical Shock and Burn Hazard:When using instruments such as oscilloscopes to work on live equipment, the oscilloscope’schassis should be grounded and a differential amplifier input should be used. Care should beused in the selection of probes and leads and in the adjustment of the oscilloscope so thataccurate readings may be made. See instrument manufacturer’s instruction book for properoperation and adjustments to the instrument.Décharge Èlectrique et Risque de Brúlure :Lors de l’utilisation d’instruments (par example oscilloscope) sur des systémes en marche, le chassis del’oscilloscope doit être relié à la terre et un amplificateur différentiel devrait être utilisé en entrée.Les sondes et conducteurs doivent être choissis avec soin pour effectuer les meilleures mesures à l’aided’un oscilloscope. Voir le manuel d’instruction pour une utilisation correcte des instruments.
Fire and Explosion Hazard:Fires or explosions might result from mounting Drives in hazardous areas such as locations whereflammable or combustible vapors or dusts are present. Drives should be installed away fromhazardous areas, even if used with motors suitable for use in these locations.Risque d’incendies et d’explosions:L’utilisation des drives dans des zônes à risques (présence de vapeurs ou de poussières inflammables),peut provoquer des incendies ou des explosions. Les drives doivent être installés loin des zônesdangeureuses, et équipés de moteurs appropriés.
Strain Hazard:Improper lifting practices can cause serious or fatal injury. Lift only with adequate equipment andtrained personnel.Attention à l’Élévation:Une élévation inappropriée peut causer des dommages sérieux ou fatals. Il doit être élevé seulementavec des moyens appropriés et par du personnel qualifié.
Drives and motors must be ground connected according to the NEC.Tous les moteurs et les drives doivent être mis à la terre selon le Code Electrique National ou équivalent.
Replace all covers before applying power to the Drive. Failure to do so may result in death orserious injury.Remettre tous les capots avant de mettre sous tension le drive. Des erreurs peuvent provoquer desérieux accidents ou même la mort.
Adjustable frequency drives are electrical apparatus for use in industrial installations. Parts of theDrives are energized during operation. The electrical installation and the opening of the device shouldtherefore only be carried out by qualified personnel. Improper installation of motors or Drives maytherefore cause the failure of the device as well as serious injury to persons or material damage.Drive is not equipped with motor overspeed protection logic other than that controlled by software.Followthe instructions given in this manual and observe the local and national safety regulations applicable.Les drives à fréquence variable sont des dispositifs électriques utilisés dans des installations industriels.Une partie des drives sont sous tension pendant l’operation. L’installation électrique et l’ouverture desdrives devrait être executé uniquement par du personel qualifié. De mauvaises installations de moteurs
Warning!
8 • Chapter 1 - Safety ARTDriveG Instruction manual
ou de drives peuvent provoquer des dommages materiels ou blesser des personnes.On doit suivir lesinstructions donneés dans ce manuel et observer les régles nationales de sécurité.
Always connect the Drive to the protective ground (PE) via the marked connection terminals(PE2) and the housing (PE1). AGy Drives and AC Input filters have ground discharge currentsgreater than 3.5 mA. EN 50178 specifies that with discharge currents greater than 3.5 mA theprotective conductor ground connection (PE1) must be fixed type and doubled for redundancy.Il faut toujours connecter le variateur à la terre (PE) par les des bornes (PE2) et le châssis (PE1). Lecourant de dispersion vers la terre est supérieur à 3,5 mA sur les variateurs Brushless et sur les filtres àcourant alterné (CA). Les normes EN 50178 spécifient qu'en cas de courant de dispersion vers la terre,supérieur à 3,5 ma, la mise à la terre (PE1) doit avoir une double connexion pour la redondance.
The drive may cause accidental motion in the event of a failure, even if it is disabled, unless it hasbeen disconnected from the AC input feeder.En cas de panne, le variateur peut causer une mise en marche accidentelle, même s'il est désactivé,sauf s'il a été débranché de l'alimentateur à courant alterné.
Never open the device or covers while the AC Input power supply is switched on. Minimum timeto wait before working on the terminals or inside the device is listed in section 5.9 on Instructionmanual .Ne jamais ouvrir l’appareil lorsqu’il est suns tension. Le temps minimum d’attente avant de pouvoir travaillersur les bornes ou bien à l’intérieur de l’appareil est indiqué dans la section 5.9.
If the front plate has to be removed because of ambient temperature higher than 40 degrees, theuser has to ensure that no occasional contact with live parts may occur.Si la plaque frontale doit être enlevée pour un fonctionnement avec la température de l’environnementplus haute que 40°C, l’utilisateur doit s’assurer, par des moyens opportuns, qu’aucun contact occasionnelne puisse arriver avec les parties sous tension.
Do not connect power supply voltage that exceeds the standard specification voltage fluctuationpermissible. If excessive voltage is applied to the Drive, damage to the internal components willresult.Ne pas raccorder de tension d’alimentation dépassant la fluctuation de tension permise par les normes.Dans le cas d’ une alimentation en tension excessive, des composants internes peuvent être endommagés.
Do not operate the Drive without the ground wire connected. The motor chassis should be grounded toearth through a ground lead separate from all other equipment ground leads to prevent noise coupling.Ne pas faire fonctionner le drive sans prise de terre. Le chassis du moteur doit être mis à la terre à l’aide d’unconnecteur de terre separé des autres pour éviter le couplage des perturbations. Le connecteur de terredevrait être dimensionné selon la norme NEC ou le Canadian Electrical code.
The grounding connector shall be sized in accordance with the NEC or Canadian Electrical Code.The connection shall be made by a UL listed or CSA certified closed-loop terminal connectorsized for the wire gauge involved. The connector is to be fixed using the crimp tool specified bythe connector manufacturer.
Le raccordement devrait être fait par un connecteur certifié et mentionné à boucle fermé par lesnormes CSA et UL et dimensionné pour l’épaisseur du cable correspondant. Le connecteur doit êtrefixé a l’aide d’un instrument de serrage specifié par le producteur du connecteur.
Do not perform a megger test between the Drive terminals or on the control circuit terminals.Ne pas exécuter un test megger entre les bornes du drive ou entre les bornes du circuit de contrôle.
Because the ambient temperature greatly affects Drive life and reliability, do not install theDrive in any location that exceeds the allowable temperature. Leave the ventilation coverattached for temperatures of 104° F (40° C) or below.Étant donné que la température ambiante influe sur la vie et la fiabilité du drive, on ne devrait pasinstaller le drive dans des places ou la temperature permise est dépassée. Laisser le capot deventilation en place pour températures de 104°F (40°C) ou inférieures.
Warning!
Caution
ARTDriveG Instruction manual Chapter 1 - Safety • 9
If the Drive’s Fault Alarm is activated, consult the TROUBLESHOOTING section of this instructionbook, and after correcting the problem, resume operation. Do not reset the alarm automaticallyby external sequence, etc.Si la Fault Alarm du drive est activée, consulter la section du manuel concernant les défauts et après avoircorrigé l’erreur, reprendre l’opération. Ne pas réiniliatiser l’alarme automatiquement par une séquence externe,etc.
Be sure to remove the desicant dryer packet(s) when unpacking the Drive. (If not removed thesepackets may become lodged in the fan or air passages and cause the Drive to overheat).Lors du déballage du drive, retirer le sachet déshydraté. (Si celui-ci n’est pas retiré, il empêche la ventilationet provoque une surchauffe du drive).
The Drive must be mounted on a wall that is constructed of heat resistant material. While theDrive is operating, the temperature of the Drive's cooling fins can rise to a temperature of 194° F(90°C).Le drive doit être monté sur un mur construit avec des matériaux résistants à la chaleur. Pendant lefonctionnement du drive, la température des ailettes du dissipateur thermique peut arriver à 194°F (90°).
Do not touch or damage any components when handling the device. The changing of the isolationgaps or the removing of the isolation and covers is not permissible.Manipuler l’appareil de façon à ne pas toucher ou endommager des parties. Il n’est pas permis de changerles distances d’isolement ou bien d’enlever des matériaux isolants ou des capots.
Protect the device from impermissible environmental conditions (temperature, humidity, shock etc.)Protéger l’appareil contre des effets extérieurs non permis (température, humidité, chocs etc.).
No voltage should be connected to the output of the drive (terminals U2, V2 W2). The parallel connectionof several drives via the outputs and the direct connection of the inputs and outputs (bypass) are notpermissible.Aucune tension ne doit être appliquée sur la sortie du convertisseur (bornes U2, V2 et W2). Il n’est paspermis de raccorder la sortie de plusieurs convertisseurs en parallèle, ni d’effectuer une connexion directede l’entrée avec la sortie du convertisseur (Bypass).
A capacitative load (e.g. Var compensation capacitors) should not be connected to the output ofthe drive (terminals U2, V2, W2).Aucune charge capacitive ne doit être connectée à la sortie du convertisseur (bornes U2, V2 et W2) (par exempledes condensateurs de mise en phase).
The electrical commissioning should only be carried out by qualified personnel, who are alsoresponsible for the provision of a suitable ground connection and a protected power supplyfeeder in accordance with the local and national regulations. The motor must be protected againstoverloads.La mise en service électrique doit être effectuée par un personnel qualifié. Ce dernier est responsable del’existence d’une connexion de terre adéquate et d’une protection des câbles d’alimentation selon lesprescriptions locales et nationales. Le moteur doit être protégé contre la surcharge
No dielectric tests should be carried out on parts of the drive. A suitable measuring instrument(internal resistance of at least 10 kΩ/V) should be used for measuring the signal voltages.Il ne faut pas éxécuter de tests de rigidité diélectrique sur des parties du convertisseurs. Pour mesurer lestensions, des signaux, il faut utiliser des instruments de mesure appropriés (résistance interne minimale 10kΩ/V).
Caution
NOTE! If the Drives have been stored for longer than two years, the operation of the DC link capacitors may be impairedand must be “reformed”.
Before commissioning devices that have been stored for long periods, connect them to a power supply for twohours with no load connected in order to regenerate the capacitors, (the input voltage has to be applied withoutenabling the drive).
En cas de stockage des variateurs pendant plus de deux ans, il est conseillé de contrôler l'état des condensateursCC avant d'en effectuer le branchement. Avant la mise en service des appareils, ayant été stockés pendantlongtemps, il faut alimenter variateurs à vide pendant deux heures, pour régénérer les condensateurs : appliquerune tension d'alimentation sans actionner le variateur .
NOTE! The terms “Inverter”, “Controller” and “Drive” are sometimes used interchangably throughout the industry. Wewill use the term “Drive” in this document.
Les mots “Inverter”, “Controller” et “Drive” sont interchangeables dans le domaine industriel. Nous utiliseronsdans ce manuel seulement le mot “Drive”.
10 • Chapter 1 - Safety ARTDriveG Instruction manual
1.1 Power Supply and Grounding
1) SIEI drives are designed to be powered from standard three phase lines that are electrically symmetrical withrespect to ground (TN or TT network).
Les variateurs SIEI sont prévus pour être alimentés par un réseau triphasé équilibré avec un régime de neutrestandard (TN ou TT).
2) In case of supply with IT network, the use of delta/wye transformer is mandatory, with a secondary three phasewiring referred to ground.Si le régime de neutre est IT, nous vous recommendons d'utiliser un tranformateur triangle/étoile avec point milieuramené à la terre.
In case of a three phase supply not symmetrical to ground, an insulation loss of one of the devicesconnected to the same network can cause functional problem to the drive, if the use of a delta/wyetransformer is avoided.
Si le réseau n'est pas équilibré par rapport à la terre et qu'il n'y a pas de transformateur raingle/étoile,une mauvaise isolation d'un appareil électrique connecté au même réseau que le variateur peut luicauser des troubles de fonctionnement.
Please refer to the following connection sample.
Safetyground
L1
L2
L3
Earth
U1
/L1
V1
/L2
W1
/L3
U2
/T1
V2
/T2
W2
/T3
PE
2/
All wires (including motor ground) mustbe connected inside the motor terminal box
AC
OU
TP
UT
CH
OK
E
AC
Main
Supply
AC
INP
UT
CH
OK
E
PE
1/
Warning!
ARTDriveG Instruction manual Chapter 2 - General • 11
Chapter 2 - General
ARTDriveG (AGy) is an AC Digital Inverters for the variation of the speed of three-phase motors. The AGy can be suppliedwith a power range from 0.75kW up to 200kW (230V...480V) and from 2Hp up to 200Hp (575V).
An intermediate voltage is generated from the rectified AC voltage. The Inverter bridge then produces, from this intermediatevoltage, power supply with variable voltage and frequency, by means of sinusoidal evaluated pulse-width modulation. Thispower supply provides motors with excellent running characteristics, even in a lower range.
The power supply voltage of the various cards is obtained through a switching from the intermediate circuit voltage.
The inverter power part is based on IGBT component (Insulated Gate Bipolar Transistor). The output is protected againstshort-circuits and earth faults. It is possible to switch motors on and off during the Inverter operation (see chapter 5.2.3)
If AC motors that are not specially manufactured to operate with an inverter are used, a reduction of 5...10% in suppliedcurrent must be taken into account. In case that the rated torque is requested even in the low frequency range, furtherreductions of the heat will be obtained by an external fan. If no assisted ventilation is available, oversizing of the power ofthe motor will be necessary. In both cases we suggest to consult the motor manufacturer.
For mechanical reasons (bearings, unbalanced mass, etc.) the motor manufacturer should be consulted when the motoris operated above the rated frequency.
AGy Inverters can be controlled in different ways:
- via terminal strip on the drive
- via an operator keypad
- via a standard PC program through RS 485 interface
ARTDriveG allows a smooth open-loop control and by using EXP-ENC-AGY option closed-loop control. With closed-loopcontrol, an encoder (a pulse generator) provides speed feedback information.
The power section and the control electronics are galvanically isolated.
12 • Chapter 2 - General ARTDriveG Instruction manual
Features
- Supply voltages generated by switching starting from the intermediate circuit voltage.
- Reduction of motor noise is achieved by the use of a special PWM control procedure.
- The output of the Inverter is protected against short circuits and earth faults.
- Motors can be switched on and off at the Inverter output (see chapter 5.2.4 of the manual).
- The Inverter is protected against overcurrents, undervoltages and overvoltages.
- Voltage dips (up to 15 ms for the power section) can be bridged; for the control section (see chapter 7.6 for the automaticrestart programmation).
- Sinusoidal output current generated by means of sinusoidally evaluated pulse-width modulation
- Excellent motor running characteristics, even in the lower frequency range.
- Programmable slip compensation reduces load-initiated changes in speed to a minimum.
- Voltage can be boosted in the lower frequency range, either manually or automatically (boost).
- Automatic voltage and frequency adjustment under an overload ensures the Inverter cannot stall.
- Parameters can be set either via a keypad or via an RS 485 interface.
- Reference value in the form of an analog signal 0...10 V, -10...10V, 0...20 mA, 4...20 mA as a frequency or via a serialinterface.
- Ramp function generator with linear or S-shaped ramp.
- Direct current braking by commands:
a - thru digital input;
b - automatic injection below a set frequency;
c - Before starting the motor; used with pump and fan drives which are driven by the medium or by the air and arealready turning before the drive is started. D.C. braking prevents the Inverter being switched on when alreadyturning.
- A range of voltage-frequency characteristics can be selected.
- Overload control.
- The last alarm 4 messages can be stored. Alarm messages are retained even after power failure.
- Open-loop or closed-loop operation, as desired.
- Indication via a potential-free contact and via the interface when a preselected speed is exceeded. Example of anapplication: indication of stationary drive.
- Control via an RS 485 serial interface.
- Internal brake unit.
- Programmable logic
- Save parameters from the keyboard
- Recovery of parameters from the keyboard
- Change of language set up of the keyboard from E@syDrives
Accessories / Options
- Drive version (“-C”) with CANopen / DeviceNet integrated.
- External EMC input filters.
- External Input / Output chokes.
- External braking resistors (connected between terminals C and BR1).
- Encoder expansion card: EXP-ENC-AGY (code S525L)
- Remote keypad kit (code S5WW5).
- E2PROM key: PRG-KEY (code S6F38).
- I/O expansion card: EXP-D6A1R1-AGy (code S524L).
- 120 Vac digital input interface card : EXP-D8-120 (code S520L).
- Profibus interface card: SBI-PDP-AGy (code S5H28).
ARTDriveG Instruction manual Chapter 3 Inspection Procedure, Component Identification and Standard Specification • 13
Chapter 3 - Inspection Procedure, Component Identificationand Standard Specification
3.1 Upon Delivery Inspection Procedures
3.1.1 General
A high degree of care is taken in packing the AGy Drives and preparing them for delivery. They should only be transportedwith suitable transport equipment (see weight data). Observe the instructions printed on the packaging. This also applieswhen the device is unpacked and installed in the control cabinet.
Upon delivery, check the following:
- the packaging for any external damage
- whether the delivery note matches your order.
Open the packaging with suitable tools. Check whether:
- any parts were damaged during transport
- the device type corresponds to your order
In the event of any damage or of an incomplete or incorrect delivery please notify the responsible sales offices immediately.
The devices should only be stored in dry rooms within the specified temperature ranges .
NOTE! A certain degree of moisture condensation is permissible if this arises from changes in temperature (seesection 3.4.1, “Permissible Environmental Conditions”). This does not, however, apply when the devicesare in operation. Always ensure that there is no moisture condensation in devices that are connected tothe power supply!
3.1.2 Inverter Type Designation
The technical specification of the AGy Drive is stated in the type code. Example:
AGy-EV-2040-KB X-X -X
AGy Drive Evolution series
Drive mechanical dimension
Drive kW rating or Hp (for 575V series)
K=keypad included
X=Software standard
B=Integrated braking unit; X= NOT Integrated braking unit
Mains Supply Type
[Blank]=NOT integrated CANopen/DeviceNet
The AGy Drive selected depends on the rated current of the motor. The rated output current at the appropriate serviceconditions must be greater than or equal to the motor current required.
The speed of the three-phase motor is determined by the number of pole pairs and the frequency (nameplate, data sheet)of the motor concerned. Operation above the rated frequency and speed of the motor must take into account thespecifications given by the manufacturer losses (bearings, unbalance etc.). This also applies to temperature specificationsfor continuous operation under 20 Hz (poor motor ventilation, not applicable to motors with external ventilation).
14 • Chapter 3 Inspection Procedure, Component Identification and Standard Specification ARTDriveG Instruction manual
3.1.3 Nameplate
Check that all the data stated in the nameplate enclosed to the inverter correspond to what has been ordered.
Figure 3.1.3.1: Identification Nameplate (example for 575V series)
Type : AGyEV- 3010 -KBX-5 S/N: 03062492
Inp: 575Vac 50/60Hz 3Ph
15A @575 Vac With line Choke
Out : 0-575Vac 400Hz 3Ph 10Hp @ 575Vac
13,3A @575V Cont. Serv. 12,6A @575Vac Ovld 150%
SHORT CIRCUIT WITH STAND RATING 10KA, 600Vac max
LISTED
INDUSTRIAL CONTROL EQUIPMENT
31KF
SIEI SPA
®
Type: Inverter modelS/N: Serial numberMain Power In: Power supply voltage - AC Input current - FrequencyMain Power Out: Output voltage - Output current - Output frequency
Figure 3.1.3.2: Firmware & Card Revision Level Nameplate
Firmware HW release S/N 0162330 Prod.R elease D F P R S BU SW . CFG CONF
C 2.03 A -.A -.- 1.000 A1
Figure 3.1.3.3: Nameplates Position
ARTDriveG Instruction manual Chapter 3 Inspection Procedure, Component Identification and Standard Specification • 15
3.2 Component Identification
Figure 3.2.1: Basic Setup of Frequency Inverter
An AGy Drive converts the constant voltage and frequency of a three-phase power supply into a direct voltage and thenconverts this direct voltage into a new three-phase power supply with a variable voltage and frequency. This variablethree-phase power supply can be used for the infinitely variable adjustment of the speed of three-phase asynchronousmotors.
1 AC Input supply voltage: 230V ... 480V for “AGy...-4 and 575V for “AGy...-5”.
2 AC Mains choke (see section 5.7.1).
3 Three-phase rectifier bridge
Converts the alternating current into direct current using a three phase full wave bridge.
4 DC intermediate circuit
With charging resistor and smoothing capacitor.
Direct voltage (UDC
) = √2 x Mains voltage (ULN
)
5 IGBT inverter
Converts direct voltage to a variable three-phase alternating voltage with variable frequency.
6 Configurable control section
Modules for open-loop and closed-loop control of the power section. This is used for processing control commands,reference values and actual values.
7 Output voltage:
Three-phase, variable alternating voltage from 0 up to 94% of Mains voltage (ULN
).
8 Encoder (option)
For speed feedback (see section 4.4.2).
16 • Chapter 3 Inspection Procedure, Component Identification and Standard Specification ARTDriveG Instruction manual
3.3 Standard Specifications
3.3.1 Permissible Environmental Conditions
Table 3.3.1.1: Environmental Specification
[°C] 0 … +40; +40…+50 with derating
[°F] 32 … +104; +104…+122 with derating
Installation location
Installation altitude
Temperature:
operation1)
operation2)
storage
transport
Air humidity:
operation
storage
transport
Air pressure:
operation [kPa] 86 to 106 (class 3K3 as per EN50178)
storage [kPa] 86 to 106 (class 1K4 as per EN50178)
transport [kPa] 70 to 106 (class 2K3 as per EN50178)
General standards
Safety
Climatic conditions
Clearance and creepage
Vibration
EMC compatibility
Rated input voltages
ApprovalsTGy0020
-20…+60°C (-4…+140°F), for devices with keypad
IP20 according to EN 60529
IP54 for the cabinet with externally mounted heatsink; only for sizes from 1007 to 3150 (230V…480V) and
from 2002 to 3020 (575V)
EN 50178, UL508C, UL840. Overvoltage category for mains connected circuits: III; degree of pollution 2
EN 60068-2-6, test Fc.
-20…+55°C (-4…+131°F), for devices with keypad
CE, UL, cUL, CSA
E N V I R O N M E N T
S T A N D A R D
Pollution degree 2 or better (free from direct sunligth, vibration, dust, corrosive or inflammable gases, fog,
vapour oil and dripped water, avoid saline environment)
Up to 1000m (3281 feet) above sea level; for higher altitudes a current reduction of 1.2% for every 100m (328
feet) of additional height applies .
A light condensation of moisture may occur for a short time occasionally if the device is not in operation (class 2K3 as per
EN50178)
EN61800-3/A11 (see “EMC Guidelines” instruction book)
IEC 60038
-25…+70°C (-13…+158°F), class 2K3 per EN50178
TA Ambient temperature
0…40°C (32°…104°F)
0…50°C (32°…122°F)
-25…+55°C (-13…+131°F), class 1K4 per EN50178
Protection degree
95 %3)
60 g/m4)
EN 61800-1, IEC 143-1-1.
5 % to 85 %, 1 g/m3
to 25 g/m3
without moisture condensation or icing (Class 3K3 as per EN50178)
5% to 95 %, 1 g/m3
to 29 g/m3
(Class 1K3 as per EN50178)
EN 50178, UL 508C
EN 60721-3-3, class 3K3. EN 60068-2-2, test Bd.
1) Over 40°C (104°F):
- current reduction of 2% of rated output current per K
- remove front plate (better than class 3K3 as per EN50178)
2) Current derated to 0.8 rated ouput current
Over 40°C (104°F): removal of the top cover (better than class 3K3 as per EN50178)
3) Greatest relative air humidity occurs with the temperature @ 40°C (104°F) or if the temperature of the device is broughtsuddenly from -25 ...+30°C (-13°...+86°F).
4) Greatest absolute air humidity if the device is brought suddenly from 70...15°C (158°...59°F).
ARTDriveG Instruction manual Chapter 3 Inspection Procedure, Component Identification and Standard Specification • 17
Disposal of the Device
The AGy Drive can be disposed as electronic scraps in accordance with the currently valid national regulations for thedisposal of electronic parts.
The plastic covering of the Drives are recyclable: the material used is >ABS+PC< .
3.3.2 Mains Connection and Inverter Output
The AGy Drive must be connected to an AC mains supply capable of delivering a symmetrical short circuit current loweror equal to the values indicated on table 3.3.2.1. For the use of an AC input choke see paragraph 5.7.1.
Note from the table of paragraph 3.3.2.1. the allowable mains voltages. The cycle direction of the phases is free.
Voltages lower than the min. tolerance values can cause the block of the inverter.
It is possible to obtain the automatical restart of the inverter, after another failure has occured (For further information, seeparagraph 7.6, Autoreset Configuration section).
NOTE! In some cases AC Input chokes, and possibly noise suppression filters should be fitted on the ACInput side of the device. See chapter “Chokes/Filters”.
Adjustable Frequency Drives and AC Input filters have ground discharge currents greater than 3.5 mA. EN 50178 specifiesthat with discharge currents greater than 3.5 mA the protective conductor ground connection (PE1) must be fixed type.
18 • Chapter 3 Inspection Procedure, Component Identification and Standard Specification ARTDriveG Instruction manual
Table 3.3.2.1-A: AC Input/Output Specifications for 230V...480V Drive Kw/Hp Rating
1007
1015
1022
1030
2040
2055
2075
3110
3150
4185
4220
4300
4370
5450
5550
6750
7900
71100
71320
81600
82000
Invert
er
Outp
ut(I
EC
146
cla
ss1),
Continuous
serv
ice
(@400V
ac)
[kV
A]
1.6
2.7
3.8
56.5
8.5
12
16.8
22.4
27
32
42
55
64
79
98
128
145
173
224
277
Invert
er
Outp
ut(I
EC
146
cla
ss2),
150%
overload
for
60s
(@400V
ac)
[kV
A]
1.4
2.4
3.4
4.5
5.9
7.7
10.9
15.3
20.3
24.6
29
38.2
50
58.3
72
89.2
116.5
132
157.5
204
252
PN
mot(r
ecom
mended
moto
routp
ut)
: @U
LN=
230V
ac;f S
W=
defa
ult;IE
C146
cla
ss
1[k
W]
0.3
70.7
51.1
1.5
2.2
34
5.5
7.5
10
11
18.5
22
22
30
37
55
55
75
90
100
@U
LN=
230V
ac;f S
W=
defa
ult;IE
C146
cla
ss
2[k
W]
0.3
70.7
51.1
1.5
2.2
34
5.5
7.5
911
15
18.5
22
30
37
45
55
55
90
100
@U
LN=
230V
ac;f S
W=
defa
ult;IE
C146
cla
ss
1[H
p]
0.5
01
1.5
23
45
7.5
10
10
15
25
30
30
40
50
75
75
100
125
125
@U
LN=
230V
ac;f S
W=
defa
ult;IE
C146
cla
ss
2[H
p]
0.5
01
1.5
23
45
7.5
10
10
15
20
25
30
40
50
60
75
75
100
125
@U
LN=
400V
ac;f S
W=
defa
ult;IE
C146
cla
ss
1[k
W]
0.7
51.5
2.2
34
5.5
7.5
11
15
18.5
22
30
37
45
55
75
90
110
132
160
200
@U
LN=
400V
ac;f S
W=
defa
ult;IE
C146
cla
ss
2[k
W]
0.7
51.5
2.2
34
5.5
7.5
11
15
18.5
22
30
37
45
55
55
90
90
110
160
200
@U
LN=
460V
ac;f S
W=
defa
ult;IE
C146
cla
ss
1[H
p]
12
33
57.5
10
15
20
25
30
40
50
60
75
100
125
150
150
200
250
@U
LN=
460V
ac;f S
W=
defa
ult;IE
C146
cla
ss
2[H
p]
0.7
51.5
23
57.5
10
15
20
20
25
30
40
50
60
75
100
125
150
200
250
U2
Max
outp
utvoltage
[V]
f 2M
ax
outp
utfr
equency
[Hz]
I 2N
Rate
doutp
utcurr
ent:
@U
LN=
230-4
00V
ac;f S
W=
defa
ult;
IEC
146
cla
ss
1[A
]2.4
45.6
7.5
9.6
12.6
17.7
24.8
33
39
47
63
79
93
114
142
185
210
250
324
400
@U
LN=
230-4
00V
ac;f S
W=
defa
ult;
IEC
146
cla
ss
2[A
]2.2
3.6
5.1
6.8
8.7
11.5
16.1
22.5
30
35
43
57
72
85
104
129
168
191
227
295
364
@U
LN=
460V
ac;f S
W=
defa
ult;
IEC
146
cla
ss
1[A
]2.1
3.5
4.9
6.5
8.3
12.1
15.4
23.1
29.7
34
41
55
69
81
99
124
161
183
218
282
348
@U
LN=
460V
ac;f S
W=
defa
ult;
IEC
146
cla
ss
2[A
]1.9
3.2
4.4
5.9
7.6
11.0
14.0
21.0
27.0
31
37
50
63
74
90
112
146
166
198
257
317
f SW
sw
itchin
gfr
equency
(Defa
ult)
[kH
z]
f SW
sw
itchin
gfr
equency
(Hig
her)
[kH
z]
4-
I ovld
(sh
ort
term
ove
rlo
ad
cu
rre
nt,
20
0%
of
I 2N
for
0.5
so
n6
0s)
[A]
4.4
7.2
10.2
13.6
17.4
23
32.2
45
60
70
86
116
144
170
208
258
338
382
454
n.a
.n.a
.D
era
ting
facto
r:
Voltage
Facto
rK
Vat460
Vac
**0.9
60.8
70.9
30.9
Tem
p.F
acto
rK
Tfo
ram
bie
ntte
mpera
ture
Sw
itchin
gfr
equency
KF
AC
UL
NIn
putvoltage
[V]
AC
Inputfr
equency
[Hz]
I NA
CIn
putcurr
entfo
rcontinuous
serv
ice
:
-C
onnection
with
3-p
hase
reacto
r
@230V
ac;IE
C146
cla
ss
1[A
]1.7
2.9
45.5
*7
9.5
14
*18.2
25
*32.5
39
55
69
84
98
122
158
192
220
275
n.a
.
@400V
ac;IE
C146
cla
ss
1[A
]1.9
3.3
4.5
6.2
*7.9
10.7
15.8
*20.4
28.2
*36.7
44
62
77
94
110
137
177
216
247
309
365
@460V
ac;IE
C146
cla
ss
1[A
]1.7
2.9
3.9
5.4
*7
9.3
13.8
*17.8
24.5
*32.5
37
53
66
82
96
120
153
188
214
268
318
-C
onnection
without3-p
hase
reacto
r
@230V
ac;IE
C146
cla
ss
1[A
]3.6
4.4
6.8
7.9
*11
15.5
21.5
*27.9
35.4
*
@400V
ac;IE
C146
cla
ss
1[A
]3.9
4.8
7.4
9*
12
16.9
24.2
*30.3
40
*
@460V
ac;IE
C146
cla
ss
1[A
]3.4
4.2
6.4
7.8
*10.4
14.7
21
*26.4
34.8
*
Ma
xsh
ort
circu
itp
ow
er
with
ou
tlin
ere
acto
r(Z
min
=1
%)
[kV
A]
160
270
380
500
650
850
1200
1700
2250
2700
3200
4200
5500
6400
7900
9800
12800
14500
17300
22400
27700
Overv
oltage
thre
shold
[V]
Underv
oltage
thre
shold
[V]
Bra
kin
gIG
BT
Unit
Sta
ndard
inte
rnal(w
ith
exte
rnalre
sis
tor)
;M
AX
Bra
kin
gto
rque
:
TG
y0
03
1g
b
50
/60
Hz
±5
%
23
0V
-15
%…
48
0V
+1
0%
,3
Ph
440V
DC
(for
230V
AC
main
s),
820V
DC
(for
400V
AC
main
s),
820V
DC
(for
460V
AC
main
s)
For
these
types
an
exte
rnalin
ducta
nce
isre
com
mended
230V
DC
(for
230V
AC
main
s),
380V
DC
(for
400V
AC
main
s),
415V
DC
(for
460V
AC
main
s)
Option
inte
rnal(w
ith
exte
rnalre
sis
tor)
;
Bra
kin
gto
rque
150%
150%
AG
yD
rive
Typ
e-
kW
rati
ng
OU
TP
UT
8
0.8
@5
0°C
(12
2°F
)
200
500
8 16
Exte
rnalbra
kin
gunit
(optional)
4
0.9
4x
UL
N(A
CIn
putvoltage)
0.8
7
IN
PU
T
0.8
7
0.7
for
hig
her
f sw
*: For the specified power sizes, the external reactor is strongly recommended
**: Linear shapes for KV, KT, respectively in the ranges [400, 460] Vac, [40, 50]°C, (104, 122)°F.
Example: for AC mains = 440VAC, 400V/440V = 0.90 = KV
ARTDriveG Instruction manual Chapter 3 Inspection Procedure, Component Identification and Standard Specification • 19
Table 3.3.2.1-B: AC Input/Output Specifications for 575V Drive Hp Rating
AG
yD
riv
eTy
pe
-H
pra
tin
g2
00
22
00
32
00
53
00
73
01
03
01
53
02
04
02
54
03
04
04
05
05
05
06
05
07
56
10
07
12
57
15
08
20
0
Invert
er
Outp
ut(I
EC
146
cla
ss1),
Continuous
serv
ice
[kV
A]
3.8
4.5
7.0
10
.81
3.7
18
.62
4.1
30
36
46
58
69
86
10
91
36
15
72
10
Invert
er
Outp
ut(I
EC
146
cla
ss2),
150%
overload
for
60s
[kV
A]
3.4
4.1
6.3
9.8
12
.51
6.9
21
.92
73
34
25
36
37
89
91
24
14
31
91
PN
mot(r
ecom
mended
moto
routp
ut)
:
@U
LN=
575V
ac;f S
W=
defa
ult;IE
C146
cla
ss
1[H
p]
23
57
.51
01
52
02
53
04
05
06
07
51
00
12
51
50
20
0
@U
LN=
575V
ac;f S
W=
defa
ult;IE
C146
cla
ss
2[H
p]
23
57
.51
01
52
02
53
04
05
06
07
51
00
12
51
50
20
0
U2
Max
outp
utvoltage
[V]
f 2M
ax
outp
utfr
equency
(*)
[Hz]
I 2N
Rate
doutp
utcurr
ent:
@U
LN=
575V
ac;f S
W=
defa
ult;
IEC
146
cla
ss
1[A
]3
.84
.57
.01
0.8
13
.81
8.7
24
.23
03
64
65
86
98
61
09
13
71
58
211
@U
LN=
575V
ac;f S
W=
defa
ult;
IEC
146
cla
ss
2[A
]3
.54
.16
.49
.81
2.6
17
.02
2.0
27
33
42
53
63
78
99
12
51
44
19
2
f SW
sw
itchin
gfr
equency
(Defa
ult)
[kH
z]
f SW
sw
itchin
gfr
equency
(Hig
her)
[kH
z]
2
I ovld
(short
term
overload
curr
ent,
200%
ofI 2
Nfo
r0.5
son
60s)
[A]
7.0
8.2
12
.81
9.6
25
.23
44
45
46
68
41
06
12
61
56
19
82
49
28
83
84
Dera
ting
facto
r:
KT
for
am
bie
ntte
mpera
ture
KF
for
sw
itchin
gfr
equency
0.8
70
.64
0.8
7n
.a.
UL
NA
CIn
putvoltage
[V]
AC
Inputfr
equency
[Hz]
I NA
CIn
putcurr
entfo
rcontinuous
serv
ice
:
-C
onnection
with
3-p
hase
reacto
r
@575V
ac;IE
C146
cla
ss1
[A]
3.8
4.7
7.4
11
.71
51
9.8
25
.93
13
54
66
06
88
511
41
40
16
32
16
-C
onnection
without3-p
hase
reacto
r
@575V
ac;IE
C146
cla
ss1
[A]
5.3
6.1
9.9
17
20
.72
7.6
33
.9
Max
short
circuit
pow
er
withoutlin
ere
acto
r(Z
min
=1%
)[k
VA
]3
80
45
07
00
10
80
13
70
18
60
24
10
30
00
36
00
46
00
58
00
69
00
86
00
10
90
01
37
00
15
70
02
10
00
Overv
oltage
thre
shold
[V]
Underv
oltage
thre
shold
[V]
Bra
kin
gIG
BT
Unit
(sta
ndard
drive)
TG
y0
03
0
n.a
.0
.8fo
rh
igh
er
f SW
OU
TP
UT
40
0
42
4
10
00
VD
C
56
5V
DC
(fo
r5
75
VA
Cm
ain
s)
Exte
rnalbra
kin
gunit
(optional)
Optionalin
tern
albra
kin
gunit
(with
exte
rnal
resis
tor)
;bra
kin
gto
rque
150%
Sta
ndard
inte
rnal(w
ith
exte
rnalre
sis
tor)
;B
rakin
gto
rque
150%
DC
ch
oke
inte
gra
ted
0.9
4x
ULN
(AC
Inputvoltage)
8
20
0
168
IN
PU
T
0.7
for
hig
he
rf S
W
0.8
@50°C
(122°F
)
500
-10%
/575V
±10%
,3P
h
50/6
0H
z±5%
20 • Chapter 3 Inspection Procedure, Component Identification and Standard Specification ARTDriveG Instruction manual
3.3.3 AC Input Current
NOTE! The Input current of the Drive depends on the operating state of the connected motor. The tables3.3.2.1 shows the values corresponding to rated continuous service, keeping into account typicaloutput power factor for each size
3.3.4 AC Output
The output of the AGy Drive is ground fault and phase to phase output short protected.
NOTE! The connection of an external voltage to the output terminals of the Drive is not permissible! It is allowed todisconnect the motor from the Drive output, after the Drive has been disabled.
The rated value of direct current output ( ICONT
) depends on the supply voltage ( KV), the ambient temperature ( K
T) and the
switching frequency (KF) if higher than the default setting:
ICONT
= I2N
x KV x K
T (Values of derating factor are the listed on tables 3.3.2.1) with an overload capacity I
MAX = 1.5 x I
CONT
for 60 seconds.
Recommended motor outputs
The coordination of the motor rated powers with the Drive type presented in the table 3.3.2.1 refers to the use of standardmotors with a rated voltage equal to the rated voltage of the input supply.
As for those motors with different voltages, the type of Drive to use is determined by the rated current of the motor.
NOTE! Max allowed overload:
136% . I2N
cl.1 ≡ 150% . I2N
cl.2
Table 3.3.4.1 shows nominal current values for typical service profiles (Ambient temperature =40°C[104°F], standard switching frequency).
Similar criteria apply for operation with additional derating factors.
Table 3.3.4.1: Nominal Drive Current
I2N (1) I2N (2) I2N (3) I2N (4) I2N (5) I2N (6)
[A] [A] [A] [A] [A] [A]
1007 2.4 2.2 2.1 1.9 2002 3.8 3.5
1015 4.0 3.6 3.5 3.2 2003 4.5 4.1
1022 5.6 5.1 4.9 4.4 2005 7.0 6.4
1030 7.5 6.8 6.5 5.9 3007 10.8 9.8
2040 9.6 8.7 8.3 7.6 3010 13.8 12.6
2055 12.6 11.5 12.1 11 3015 18.7 17.0
2075 17.7 16.1 15.4 14 3020 24.2 22.0
3110 24.8 22.5 23.1 21.0 4025 30 27
3150 33 30 29.7 27 4030 36 33
4185 39 35 34 31 4040 46 42
4220 47 43 41 37 5050 58 53
4300 63 57 55 50 5060 69 63
4370 79 72 69 63 5075 86 78
5450 93 85 81 74 6100 109 99
5550 114 104 99 90 7125 137 125
6750 142 129 124 112 7150 158 144
7900 185 168 161 146 8200 211 192
71100 210 191 183 166
71320 250 227 218 198
81600 324 295 282 257
82000 400 364 348 317TGy0040gb
AG
y…
-4(2
30
V…
48
0V
)
Drive TypeDrive Type
AG
y…
-5(5
75
V)
(1): I2N Rated output current (@ ULN=230-400Vac),Continuous service, no overload (IEC 146 class 1)
(2): I2N Rated output current (@ ULN=230-400Vac), Overloadservice 150%x60s followed by IN, min.cycle time 360s (IEC146 class 2).
(3): I2N x kV Rated output current (@ ULN=460-480Vac),Continuous service, no overload (IEC 146 class 1)
(4): I2N x kV Rated output current (@ ULN=460-480Vac),Overload service 150%x60s followed by IN, min.cycle time360s (IEC 146 class 2).
(5) I2N Rated output current (@ ULN=575Vac), continuousservice, no overload (IEC 146 classe 1).
(6) I2N Rated output current (@ ULN=575Vac), overloadservice 150%x60s followed by IN, min. cycle time 360s(IEC 146 classe 2).
ARTDriveG Instruction manual Chapter 3 Inspection Procedure, Component Identification and Standard Specification • 21
3.3.5 Open-Loop and Closed-Loop Control Section
No. 3 Analog inputs 3 Programmable Analog inputs:
. Analog input 1 ±10 V 0.5 mA max, 10 bit + sign / unipolar or bipolar (0...10V=default)
. Analog input 2 ±10 V 0.5 mA max, 10 bit + sign / unipolar or bipolar (±10 V =default)
. Analog input 3 0...20 mA, 4...20mA 10 V max, 10 bit (4...20mA=default)
No. 2 Analog outputs 2 Programmable Analog outputs: ±10 V / 5 mA max
. Analog output 1 = -10...+10V, 10 bit, Frequency output absolute value (default)
. Analog output 2 = -10...+10V, 10 bit, Output current (default)
No. 8 Digital inputs 8 Programmable Digital inputs: 0...24V / 6 mA
. Digital input 8 = Reverse (default)
. Digital input 7 = Run (default)
. Digital input 6 = External fault NO (default)
. Digital input 5 = Alarm state (default)
. Digital input 4 = Jog (default)
. Digital input 3 = Stop (3-wires) (default)
. Digital input 2 = Freq sel 2 (default)
. Digital input 1 = Freq sel 1 (default)
No. 4 Digital output 4 Programmable Digital outputs:
. Digital output 1 = Drive ready (default)
. Digital output 2 = Steady state(default)
. Digital output 3 = Alarm state (default)
. Digital output 4 = Motor running (default)
NOTE! Dig. out. 1 / 2 > open collector type: 50V / 50mA
Dig. out. 3 / 4 > relay output type: 230Vac-1A / 30Vdc-1A
Internal voltage supply
Load capacity + 24 Vdc 50 mA Terminal 1
+ 10 Vdc 10 mA Terminal 29
- 10 Vdc 10 mA Terminal 32+ 24 Vdc 300 mA Terminal 9
Tollerance + 10 Vdc ±3 %+ 24 Vdc ±10 %
No.1 Digital Encoder Input (with EXP-ENC-AGY optional card)
Voltage 5/8/24 V
Type 1channel/2channels. No zero.
Max frequency 150kHz
3.3.6 Accuracy
Reference value : Resolution of Reference preset via terminals 0.1 Hz
Resolution of Reference preset via interface 0.01 Hz
Speed: Open-loop speed control: Load-dependent speed fluctuations are minimized by
slip compensation. The accuracy depends on the motor connected.
22 • Chapter 3 Inspection Procedure, Component Identification and Standard Specification ARTDriveG Instruction manual
NOTE:
ARTDriveG Instruction manual Chapter 4 - Installation Guidelines • 23
Chapter 4 - Installation Guidelines
4.1 Mechanical Specification
Figure 4.1.1: AGy Dimensions for Sizes 1007...3150 (230V...480V) and 2002... 3020 (575V)
Table 4.1.1: AGy Dimensions and Weights for Sizes 1007...3150 (230V...480V) and 2002... 3020 (575V)
Weight
a b c d D1 D2 E1 E2 kg (lbs)
1007 3.5 (7.7)
1015 3.6 (7.9)
1022
1030
2040
2055
2075
3110
3150
2002
2003
2005 4.8 (10.6)
3007
3010
3015
3020agy3100
Drive dimensions: mm (inch)
151.5 (5.9) 306.5 (12.0) 199.5 (7.8) 62 (2.4) 115 (4.5) 296.5 (11.6)
208 (8.2)
69 (2.7)
115 (4.5)
8.8 (19.4)
3.7 (8.1)
115 (4.5) 299.5 (11.7)
164 (6.5) 315 (12.4)
4.95 (10.9)
8.6 (19)
4.6 (10.1)
8.2 (18)
310.5 (12.2)208 (8.2) 323 (12.7) 240 (9.5) 168 (6.6)
240 (9.5)
62 (2.4)
84 (3.3)
84 (3.3)
Type
AG
y…
-4(2
30
V…
48
0V
)A
Gy
…-5
(57
5V
)
310.5 (12.2)
105.5 (4.1)
151.5 (5.9)
168 (6.6)
306.5 (12.0)
323 (12.7)
199.5 (7.8)
164 (6.5) 315 (12.4)
296.5 (11.6)
69 (2.7)
115 (4.5)
299.5 (11.7)
24 • Chapter 4 - Installation Guidelines ARTDriveG Instruction manual
Figure 4.1.2: AGy Mounting Methods for Sizes 1007...3150 (230V...480V) and 2002... 3020 (575V)
Mounting wall (D)Mounting with external dissipator (E)
E2 E4
E5
E3
E1
d
Table 4.1.2: AGy Mounting Methods for Sizes 1007...3150 (230V...480V) and 2002... 3020 (575V)
E1 E2 E3 E4 E5 Ø d
1007
1015
1022
1030
2040
2055
2075
3110
3150
2002
2003
2005
3007
3010
3015
3020agy3101
284 (11.2)
299.5 (11.8)164 (6.5) 315 (12.4)
145.5 (5.7)
199 (7.8)
9 (0.35)
AG
y…
-4(2
30
V…
48
0V
)A
Gy
…-5
(57
5V
)
M5
99.5 (3.9)
145.5 (5.7)
199 (7.8)
284 (11.2)
115 (4.5) 299.5 (11.7)
299.5 (11.8)
Type
9 (0.35)
Drive dimensions: mm (inch)
69 (2.7)
115 (4.5)
299.5 (11.7)
164 (6.5) 315 (12.4)
ARTDriveG Instruction manual Chapter 4 - Installation Guidelines • 25
Figure 4.1.3 : AGy Dimensions for Sizes 4185...82000 (230V...480V) and 4025... 8200 (575V)
ca
D1
b
Figure 4.1.4 : AGy Mounting Methods for Sizes 4185...82000 (230V...480V) and 4025... 8200 (575V)
D1
D2 D2
D3 D3 D3 D3
D4
Mounting wall (D)
Table 4.1.3 : AGy Dimensions and Weights for Sizes 4185...82000 (230V...480V) and 4025... 8200 (575V)
Weight
kg (Ibs) a b c D1 D2 D3 D4 Ø
4185
4220
4300 22 (48.59)
4370 22.2 (48.9)
5450
5550
6750 59 (130) 741 (29.2) 725 (28.5)
7900 75.4 (166.1)
71100 80.2 (176.7)
71320 86.5 (190.6)
81600
82000
4025
4030
4040 31.6 (67.9)
5050
5060
5075
6100 83 (183) 921 (36.2) 903 (35.5)
7125
7150
8200 131 (288.6) 1183 (46.6)agy3105gb
442 (17.4) 947 (37.3)
475 (18.7)
M6
1095 (43.1)
297.5 (11.7)
150 (15.91)
555 (21.2)
590 (23.2)
268 (10.5)
309 (12.1) 489 (19.2)
268 (10.5)
225 (8.8)
350 (13.8)
965 (38)
509 (20)
418 (16.4) 605 (23.8)
569 (22.4)
100 (3.9)
-
- -
-
-
909 (35.8)
Drive dimensions: mm (inch)
308 (12.1)
376 (14.7) 564 (22.2)
891 (35)
150 (5.9) 550 (21.6)
AG
y..
.-5
(57
5V
)
28.6 (63.1)
34 (74.9)
47 (103.6)
Type
AG
y..
.-4
(23
0V
...4
80
V)
18 (39.6)
109 (240.3)
- -
118 (260.1) 1113 (43.8) - - 100 (3.9)509 (20)
320 (12.6)
297.5 (11.7)
26 • Chapter 4 - Installation Guidelines ARTDriveG Instruction manual
Figure 4.1.5: Keypad Positioning
To allow a confortable viewing angle, the keypad can be oriented on three different positions.
ARTDriveG Instruction manual Chapter 4 - Installation Guidelines • 27
4.2 Watts Loss, Heat Dissipation, Internal Fans and Minimum CabinetOpening Suggested for the Cooling
The heat dissipation of the Drives depends on the operating state of the connected motor. The table below shows values thatrefer to operation at default switching frequency (see section 3.3.4, “AC Output”), Tamb < 40°C (104°F), typ. motor powerfactor and nominal continuous current.
Table 4.2.1: Heat Dissipation and Required Air Flow
1
0
0
7
1
0
1
5
1
0
2
2
1
0
3
0
2
0
4
0
2
0
5
5
2
0
7
5
3
1
1
0
3
1
5
0
4
1
8
5
4
2
2
0
4
3
0
0
4
3
7
0
5
4
5
0
5
5
5
0
6
7
5
0
7
9
0
0
7
1
1
0
0
7
1
3
2
0
8
1
6
0
0
8
2
0
0
0
PV Heat dissipation:
@ULN=230Vac1) [W] 38 62 83 110 144 184 264 304 416 448 526 691 880 1000 1264 1560 1952 2280 2720 n.a. n.a.
@ULN=400Vac1) [W] 48 77 104 138 180 230 330 380 520 560 658 864 1100 1250 1580 1950 2440 2850 3400 4400 5400
@ULN=460Vac1) [W] 45 72 96.3 126.7 164.1 215.6 300.8 340 468 500 582 780 1000 1100 1390 1750 2200 2560 3050 3950 4700
1)fSW=default; I2=I2N
Airflow of fan:
Internal fan [m3/h] 11 11 11 11 11 11 11 30 30
Heatsink fans [m3/h] - 30 30 30 2x30 2x30 2x30 2x79 2x79 650 1820 2000
2
0
0
2
2
0
0
3
2
0
0
5
3
0
0
7
3
0
1
0
3
0
1
5
3
0
2
0
4
0
2
5
4
0
3
0
4
0
4
0
5
0
5
0
5
0
6
0
5
0
7
5
6
1
0
0
7
1
2
5
7
1
5
0
8
2
0
0
PV Heat dissipation:
@ULN=575Vac1) [W] 75 80 128 215 266 338 453 515 620 810 1070 1155 1480 2150 2760 2760 3250
1)fSW=default; I2=I2N
Airflow of fan:
Internal fan [m3/h] 11 11 11 30 30 30 30
Heatsink fans [m3/h] 30 30 2x30 2x79 2x79 2x79 2x79 2x80 2x80 170 650 975 975 975
agy0060gb
340
975
AGy...-5 (575) Type
AGy ...-4 (230V...480V)
Type
170 34080
NOTE! All the Drives have internal fans.
NOTE! Heat dissipation losses refer to default Switching frequency
Table 4.2.2: Minimum Cabinet Opening Suggested for the Cooling
AGy...-4
(230V...480V) Type
1
0
0
7
1
0
1
5
1
0
2
2
1
0
3
0
2
0
4
0
2
0
5
5
2
0
7
5
3
1
1
0
3
1
5
0
4
1
8
5
4
2
2
0
4
3
0
0
4
3
7
0
5
4
5
0
5
5
5
0
6
7
5
0
7
9
0
0
7
1
1
0
0
7
1
3
2
0
8
1
6
0
0
8
2
0
0
0
Control section
cm2
(sq.inch)
Heatsink
cm2
(sq.inch)72 (11.1)
AGy...-5 (575V)
Type
2
0
0
2
2
0
0
3
2
0
0
5
3
0
0
7
3
0
1
0
3
0
1
5
3
0
2
0
4
0
2
5
4
0
3
0
4
0
4
0
5
0
5
0
5
0
6
0
5
0
7
5
6
1
0
0
7
1
2
5
7
1
5
0
8
2
0
0
Control section
cm2
(sq.inch)
Heatsink
cm2
(sq.inch)
agy0070gb
2x200
(2x31)
2x370
(2x57.35)2x620 (2x96.1)
2x620 (2x96.1)2x370 (2x57.35)
36 (5.6)
Minimum cooling opening:
Minimum cooling opening:
2x150
(2x 23.5)
2 x 1600
(2 x 248)
31 (4.8)
72 (11.1)
2x15
0 (2x
23.5)
31 (4.8)
2x200
(2x31)
36 (5.6)
128 (19.8)
36 (5.6) 128 (19.8)
28 • Chapter 4 - Installation Guidelines ARTDriveG Instruction manual
4.2.1 Cooling Fans Power Supply
Sizes 1007...5550 (230V...480V) and 2002... 5075 (575V)
Power supply (+24Vac) for these fans are provided from the internal drive power supply unit.
Sizes 6750 ... 82000 (230V...480V) and 6100 ... 8200 (575V)
Power supply for these fans are internally provided from the AC input voltage:
- 6750 (230V...480V) and 6100 (575V): 0.8A@115V/60Hz, 0.45A@230V / 50Hz
- 7900 ... 71320 (230V...480V) and 7125 ... 8200 (575V): 1.2A@115V/60Hz, 0.65A@230V / 50Hz
- 81600, 82000: 1.65A@115V/60Hz, 0.70A@230V / 50Hz
Figure 4.2.1: UL Type Fans Connections on 7900 ... 71320 (230V...480V) and 7125 ... 8200 (575V).
M
~
U3
2V3
1V3
0
115
230
AU
TOTR
AFO
230VAC fans
Drive
Figure 4.2.2: UL Type Fans Connections on 6750, 82000 (230V...480V) and 6100 (575Vac).
M
~
U3
2V3
1V3
No.2 115VAC fansM
~
Drive
Figure 4.2.3: Example for External Connection
U3
2V3
1V3
230VAC
U3
2V3
1V3
115VAC
Drive Drive
(*)
NOTE! An internal fuse (2.5A 250VAC slo-blo) for 7900 ... 71320 (480V) and 7125 ... 8200 (575V) sizes is provided.On 6750 and 82000 sizes the fuse must be mounted externally.
(*) Only for drives:
- 6750, 81600 and 82000 (230V...480V)
- 6100 (575Vac)
ARTDriveG Instruction manual Chapter 4 - Installation Guidelines • 29
4.3 Installation Mounting Clearance
NOTE! The dimensions and weights specifed in this manual should be taken into consideration when thedevice is mounted. The technical equipment required (carriage or crane for large weights) should beused. Improper handling and the use of unsuitable tools may cause damage.
Figure 4.3.1: Max. Angle of Inclination
The maximum angle of inclination is 30°
NOTE! The Drives must be mounted in such a way that the free flow of air is ensured. The clearance to thedevice must be at least 150 mm (6 inches). A space of at least 50 mm (2 inches) must be ensured atthe front.
On sizes 81600 and 82000 (AGy...-4, 230...480Vac) and 8200(AGy...-5, 575Vac) the top and bottomclearance must be at least 380 mm (15 inches), on front and sides must be ensured a space of at least140 mm (5.5 inches).
Devices that generate a large amount of heat must not be mounted in the direct vicinity of the frequencyinverter.
Fastening screws should be re-tightened after a few days of operation.
Figure 4.3.2: Mounting Clearance
10 mm 0.4"( )
[140mm (5.5")]
6"150 mm ( )
[380mm (15")]
2" )50 mm (
[140mm (5.5)]
20 mm ( 0.8" )
[140mm (5.5")] 6"150 mm ( )
[380mm (15")]
10 mm 0.4"( )
[140mm (5.5")]
[...] for 81600-82000 and 8200 sizes
30 • Chapter 4 - Installation Guidelines ARTDriveG Instruction manual
4.4 Motors and Encoder
The AGy Drives are designed for open-loop and closed-loop operation of standard three-phase induction AC motors.
4.4.1 AC Induction Motors
FOR BEST RESULTS:
Select a inverter duty single cage induction motor with a minimum slip of 3-5%.
a) Minumum motor size: motor amps no less than 30% of drive rated amps at 400 VAC continuous rating
b) General purpose motors can be used but require additional AC output chokes
c) Inverter duty motors are desirable and do not require output chokes
The electrical and mechanical data of standard three-phase motors refers to a particular operating range. The followingpoints should be noted when these motors are connected to an AC Drive:
Is it possible to use standard induction motors?
With the AGy Drives it is possible to use standard induction motors. Some features of the motor have a great influence onthe obtained performances. Notice also what is stated in section 3.3.4, “AC Output”, about the voltages and the motorpower.
Star or delta connection?
Motors can be connected in both star or delta connections. Experience has shown that star connected motors have bettercontrol properties, so star connections are preferred.
Cooling
The cooling of three-phase motors is normally implemented by means of a fan that is mounted on the motor shaft. Rememberthat the output of the fan is reduced when the motor is running at lower speeds, which in certain circumstances may mean thatthe cooling is insufficient for the motor. Check with the motor manufacturer whether an external fan is required and the motorspeed range in the application concerned.
Operation above the rated speed
Due to the mechanical factors involved (bearings, unbalance of rotor) and due to the increased iron losses, consult the manufacturerof the motor if this is operated above the rated speed .
What motor data is required for connecting the frequency inverter?
Nameplate specifications- Motor rated voltage- Motor rated current- Motor rated frequency- Motor rated speed- Power factor- Pole pairs
ARTDriveG Instruction manual Chapter 4 - Installation Guidelines • 31
Motor protection
Temperature-dependent contacts in the motor winding
Temperature-dependent contacts “Klixon” type can disconnect the drive via the external control or can be reported as anexternal fault on the frequency inverter (terminal 6).
NOTE! The motor PTC interface circuit (or klixon) has to be considered and treated as a signal circuit. The connectionscables to the motor PTC must be made of twisted pairs with a shield, the cable route should not be parallel to themotor cable or far away at least 20 cm (8 inches).
Current limitation of the frequency inverter
The current limitation can protect the motor from impermissible overloads. For this the current limitation and the motoroverload control function of the Drive must be set so that the current is kept within the permissible range for the motorconcerned.
NOTE! Remember that the current limitation can control an overheating of the motor only due to overload, not due toinsufficient ventilation. When the drive is operated at low speeds the additional use of PTC resistors or temperature-dependent contacts in the motor windings is recommended, unless separate forced ventilation is available.
Output chokes
When using general purpose standard motors, output chokes are recommended to protect winding isolation in some cases.See section 5.7.2, “ Output chokes”.
4.4.2 Encoder
Encoders can be connected to the drive, only when the optional card EXP-ENC-AGY is mounted.
The card is plugged onto the regulation board through the XENC connector. The terminals on the optional card should bedirected towards the terminals of the regulation card.
AGy is able to read digital encoders with either one-channel ( AA/ ) or two-channels ( B/BA,/A ).
AGy can be configured to supply and read either HTL (+24V) or TTL (+5V or +8V) encoders, with no need for external powersupply.
Refer to the EXP-ENC-AGY manual for detailed electrical specifications and wiring guidelines.
Encoders are used to feed back a speed signal to the regulator. The encoder should be coupled to the motor shaft with abacklash free connection.
The encoder cable can be made of twisted pairs with a global shield, which connect to ground on the Drive side. Avoidconnecting the shield on the motor side. In particular cases where the cable length is more than 100 meters (328 feet),(high electromagnetic noise), it may useful to use a cable with a shield on each conductor pair, which can be connected tothe common point (0V). The global shield must always be grounded.
Table 4.4.2.1: Recommended Cable Section and Length for the Connection of Encoders
Cable section [mm2] 0.22 0.5 0.75 1 1.5
Max Length m [feet] 27 [88] 62 [203] 93 [305] 125 [410] 150 [492]avy3130
Requirements:
Digital encoder:
- max frequency: 50 kHz (select the appropriate number of pulses depending on required max. speed)
- Channels :
- one-channel (A), one-channel complementary (A,A)
- two-channel (A, B), two-channel complementary (with complementary output A,A ; B,B).
Encoder loss detection is not possible.
- Power supply: + 24V (Internal supply) or +5V (Externally supplied)
32 • Chapter 4 - Installation Guidelines ARTDriveG Instruction manual
NOTE:
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 33
Chapter 5 - Wiring Procedure
5.1 Accessing to the Connectors
NOTE! Observe the safety instructions and warnings given in this manual. The devices can be opened withoutthe use of force. Only use the tools specified.
Figure 5.1.1: AGy Removing Covers for Sizes 1007...3150 (230V...480V) and 2002...3020 (575V)
2
1
3
2
No. 2 for3110...3150 and3007...3020 sizes
Sizes 1007...2075 (230V...480V) and 2002...2005 (575V)
The terminal cover and cable entry plate of the device must be removed in order to fit the electrical connections:
- unscrew the screw (1), remove the cover of devices (2) by pressing on both sides as shown on the above figure (3).
- unscrew the two screws (4) to remove the cable entry plate.
The top cover must be removed in order to mount the option card and change the internal jumper settings:
- remove the keypad and disconnect the connector (5)
- lift the top cover on the bottom side (over the connector level) and then push it to the top (6).
Sizes 3110...3150 (230V...480V) and 3007...3020 (575V)
The terminal cover and cable entry plate of the device must be removed in order to fit the electrical connections:
- unscrew the two screws (1) and remove the cover of devices
- unscrew the two screws (4) to remove the cable entry plate.
The top cover must be removed in order to mount the option card and change the internal jumper settings:
- remove the keypad and disconnect the connector (5)
- lift the top cover on the bottom side (over the connector level) and then push it to the top (6).
34 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
Figure 5.1.2: AGy Removing Covers for Sizes 4185...82000 (230V...480V) and 4025...5075 (575V)
2 2
1
33
4
Sizes 4185...82000 (230V...480V) and 4025...8200 (575V)
The terminal cover of the device must be removed in order to fit the electrical connections: unscrew the two screw (2) andremove the cover (1).
The top cover must be removed in order to mount the option card and change the internal jumper settings: unscrew thetwo screw (3) and remove the top cover by moving it as indicated on figure (4).
In order to avoid damages of the device it is not allowed to transport it by handling on its cards !
Caution
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 35
5.2 Power Section
Table 5.2.1.1: Power Section Terminals for Sizes 1007...3150 (230V...480V) and 2002...3020 (575V)
Function Max
Motor ground connection
Braking unit resistor command (braking resistor mustbe connected between BR1 and C)
Intermediate circuit connection
AC mains voltage230V -15%…480V +10%
or 575 V ±10%See table 3.3.2.1
Motor connectionM
3Ph~
PE1 / Ground connection
U1/L1
V1/L2
W1/L3
BR1
U2/T1
V2/T2
W2/T3
C
D
PE2/
EM
EM
FEXT
FEXT
-
770 Vdc (230...480 Vac)900 Vdc (575 Vac)
1.65 x I2N
AC line volt 3Ph,1.36 I2N
Braking resistor(optional)
Reserved (active on lift software version only)
-
Note!
EM and FEXT terminalsare available on sizes3110 ... 5550 (230..480V).
Reserved (active on lift software version only)
Table 5.2.1.2: Power Section Terminals for Sizes 4185...82000 (230V...480V) and 4025...8200 (575V)
M
3Ph~
U1/L1
V1/L2
W1/L3
BR1
U2/T1
V2/T2
W2/T3
C
D
PE2/
PE1 /
EM
EM
FEXT
FEXT
MaxFunction
Motor ground connection
Braking unit resistor command (braking resistor mustbe connected between BR1 and C)
Intermediate circuit connection
AC mains voltage230V -15%…480V +10%
or 575 V ±10%See table 3.3.2.1
Motor connection
Ground connection
770 Vdc (230...480 Vac)900 Vdc (575 Vac)
1.65 x I2N
AC line volt 3Ph,1.36 I2N
Reserved (active on lift software version only)
Reserved (active on lift software version only)
Note!
EM and FEXT terminalsare available on sizes3110 ... 5550 (230..480V).
Braking resistor(optional)
-
-
Power terminals lay-out
Sizes 1007...5550 (230V...480V) and2002... 3020 (575V) The terminals of the devices are made accessible by removing the cover and the
cable entry plate (see section 5.1, “Accessing to the connectors”), on some drivetype it is also possible to extract the removable connector. All the power terminalsare located on the PV33 power card.
Sizes 6750...82000 (230V...480V) and6100...8200 (575V) The terminals of the devices are made accessible by removing the cover (see
section 5.1, “Accessing to theconnectors”).
36 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.2.1 Maximum Cable Cross Section for Power Terminals
AC input wiring is connected to a disconnected switch, which limits the size to the following ranges:
AGy...-4 (230V...400V) Type 1007 1015 1022 1030 2040 2055 2075 3110 3150 4185 4220 4300
AWG 12 8 4
[mm2] 8 10 25
Tightening torque [Nm] 3
AWG 12 8 6 8
[mm2] 8 10 10
Tightening torque [Nm] 1.6
AWG 12 8 6
[mm2] 8 10 16
Tightening torque [Nm] 3
AGy...-4 (230V...400V) Type 4370 5450 5550 6750 7900 71100 71320 81600 82000
AWG 1/0 2/0 4/0 300* 350* 4xAWG2 * = kcmils
[mm2] 50 70 95 150 185 4x35 150** **=copper bar
Tightening torque [Nm]
AWG 8
[mm2] 10
Tightening torque [Nm] 1.6
AWG
[mm2]
Tightening torque [Nm] 3
AGy...-5 (575V) Type 2002 2003 2005 3007 3010 3015 3020 4030
AWG
[mm2]
Tightening torque [Nm]
AWG
[mm2]
Tightening torque [Nm]
AWG
[mm2]
Tightening torque [Nm]
AGy...-5 (575V) Type 4040 5050 5060 5075 6100 7125 7150 8200
AWG 6 4 1/0 2/0 4/0 350*
[mm2] 16 25 50 70 95 185
Tightening torque [Nm] 2 4 12 12 10-30
AWG 10 6
[mm2] 6 16
Tightening torque [Nm] 0.9 3
AWG
[mm2]
Tightening torque [Nm]
agy4040gb
2
4025
2
2
10
6
0.9
6
16
10
6
0.9
16
terminals not available
2
50
42
4
BR1 terminals
PE1, PE2 terminals6
16
6
16
2
0.5 a 0.6 1.2 a 1.5
U1,V1,W1,U2,V2,W2,C,D
terminals
2
35
PE1, PE2 terminals14 10 8
2 4 8
0.5 a 0.6 1.2 a 1.5
0.5 a 0.6 1.2 a 1.5
BR1 terminals14 10 8
2 4 8
U1,V1,W1,U2,V2,W2,C,D
terminals
14 10 8
2 4 8
U1,V1,W1,U2,V2,W2,C,D
terminals
PE1, PE2 terminals
BR1 terminals
1.2 a 1.50.5 a 0.6
4
14
2
610
16
6
1.2 a 1.5
14 10
2 4
0.5 a 0.6 1.2 a 1.5
14
2
4 12
3
0.5 a 0.6
2
10-30
terminals not available
2
35
10
4
2
50
4
U1,V1,W1,U2,V2,W2,C,D
terminals
BR1 terminals
PE1, PE2 terminals6
16
6
16
NOTE! Use 60°C / 75°C (140°F / 167°F) copper conductor only.
The grounding conductor of the motor cable may conduct up to twice the value of the rated current ifthere is a ground fault at the output of the AGy Drive.
Caution
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 37
5.2.2 Rectification and Intermediate (D.C.) Circuit
The mains voltage is rectified and buffered by capacitors. A diode bridge with a pre-charging resistor is mounted for all sizes.
In the event of an overvoltage in the intermediate circuit (message “OV” appears in the display) or undervoltage (message“UV”), the Inverter blocks and no power can be taken from the intermediate circuit.
In normal operation the intermediate (DC) circuit voltage UDC
is equal to ULN
* 2. With oversynchronous operation of theconnected motor (deceleration or braking phase), energy is fed back into the intermediate circuit via the Inverter, resultingin an increase in the intermediate (DC) circuit voltage U
DC. Once a certain voltage is reached the Inverter is blocked, the
contact between terminals 2 and 3 (alarm relay) will open. To RESET, see paragraph 7.6, Autoreset Configuration section.
D
C
UDC
ULN
ULN ULN
Figure 5.2.3.1: Rectification and Intermediate Circuit
The automatic restart of the Inverter can be obtained after a fault indication condition has occurred (for further informationof these functions see paragraph 7.6, Autoreset Configuration section). Switching off can be prevented by extending thedeceleration ramp or by the use of a suitable braking unit (see 5.8).
38 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.2.3 Inverter
IGBTs (Insulated Gate Bipolar Transistors) for all sizes are used. The Inverter is protected against faults of overvoltage,overcurrent, short circuit between phases and ground. In the event of a fault the Inverter is disabled and the contact betweenterminals 2 and 3 will open. To RESET see paragraph 7.6, Autoreset Configuration section.
The automatic restart of the Inverter can be obtained after a fault indication condition has occurred (for further information onthese functions see paragraph 7.6, Autoreset Configuration section).
Table 5.2.4.1: Fault Indication of the Protection of the Inverter Bridge
Signalation Block caused by
OV Overvoltage
OC. OCH Overcurrent, short-circuit between phases
OC Short-circuit to ground
The variable output voltage is generated by pulse-width modulation of the intermediate (D.C.) circuit voltage. A specialprocess of sinusoidal evaluation in conjunction with the inductance of the motor produces a very good sinusoidal waveformof the output current I2. Parameters can be allocated to the voltage/frequency characteristics to adapt it to the motor to besupplied.
A number of motors can be driven in parallel at the output of the Inverter. These motors can have different speeds, evenif they have the same number of poles, since the slips of each motor change in relation of the load variation and of itscharacteristics. Motors can be connected or disconnected individually at the output. Particular care should be taken whenconnecting or disconnecting motor units.
The following should be noted: at the instant of disconnection, motors generate voltage peaks, since an inductive currentis being broken. This is not generally a problem for the output of the Inverter if the motors are low-power devices, or if anumber of other motors remain connected to the Inverter.
If the last remaining motor connected to the Inverter is being connected, it should be ensured that themagnetizing current of the motor has already decayed at the instant of disconnection. For this purposethe Inverter should be blocked and the motor disconnected only after a certain time has elapsed. Thistime is determined by the motor and will have a magnitude of approximately 0.5 to several seconds
If a motor is to be connected to an existing Inverter network during operation, it should be borne in mind that the motor willdraw a multiple of its rated current. The Inverter should be rated in such a way that the starting current lies within the rangeof the Inverter rated current. Furthermore it is possible to take into consideration the overload that the Inverter can give, ifthe connection duty cycle is within the times at which the overload is allowed.
The outputs of more than one Inverter must not be connected directly in parallel.
Caution
Caution
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 39
5.3 Regulation Section
5.3.1 R-AGy Regulation Card
Table 5.3.1.1: LEDs, Jumpers and Connectors on R-GVy-M
LED Color Function
PWR greenLED turns on when the voltage + 5V is present
and at correct level
RS 485 yellow LED turns on when Serial interface is supplied
Connector No. of pins Function
XV 2 Reserved (Fans control)
XT 10 KGB-1 and/or KGB-LCD-A keypad connector
XENC 10EXP-ENC-AGY optional board connection (for
encoder feedback)
XS 9 9-pole SUB-D connector of RS485 serial line
XKEY 5+1 QUIX-PRG key connection
XP 40 Reserved (power board connection)
XEXP 34 Reserved (expansion boards connection)
XD 10 Reserved (FW download connection)
Jumper Factory Function
Jumper to disconnect 0V24 (regulation section)
from ground.
ON = 0V24 connected to ground
OFF = 0V24 disconnected from ground
Jumper to disconnect 0V (regulation section)
from ground.
ON = 0V connected to ground
OFF = 0V disconnected from ground
Selection of the internal/external supply of the
RS485 serial interface
ON = Serial interface supplied from the
regulation section
OFF = Serial interface supplied from external
source (see chap. 5.4) and
galvanic insulation from the regulation card
Terminating resistor for the serial interface
RS485
OFF = No termination resistor
ON = Termination resistor IN
Switch FactorySwitch function of EXP-ENC-AGY optional
board
S-1 OFFOFF = HTL output logic encoder level (+24V)
ON = TTL output logic encoder level (+5V)
S-2 OFFOFF = HTL output logic encoder level (+24V)
ON = TTL output logic encoder level (+5V)
ai4050g
S1 ON
S3 S4
S2
S5 S6
ON
ON
ON
Figure 5.3.1.1: R-AGy Regulation Card
40 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.3.2 Terminal Assignments on Regulation Section
Strip 1
1
2
3
4
5
6
7
8
9
10
11
16
17
Strip 2
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
Designation
Digital Output 4 - NO
Digital Output 4 - COM
Digital Output 4 - NC
Digital Input 8
Digital Input 7
Digital Input 6
Digital Input 5
COM-IN Digital Inputs
+ 24V OUT
0 V 24 - GND Dig. Inputs
0 V 24 - GND Dig. Inputs
Digital Output 1
Digital Output 2
Function
Programmable digital relay output - Default:
Programmable digital input - Default:
Programmable digital input - Default:
Programmable digital input - Default:
Programmable digital input - Default:
Supply reference for Digital inputs
+ 24 V potential voltage reference
V 24 reference for Digital inputs
0 V 24 reference for Digital inputs
Programmable digital output - Default:
Programmable digital output - Default:
[1] Alarm state
[2] Reverse
[1] Run
[3] Ext fault NO
[5] Alarm reset
[0] Drive ready
[6] Steady state
Max
1A 30Vdc
1A 250Vac
Designation
Digital Output 3 - NO
Digital Output 3 - COM
Digital Output 3 - NC
GROUND REF
Digital Input 1
Digital Input 2
Digital Input 3
Digital Input 4
Analog Output 1
Analog Input 2
Analog Input 3
+ 10V OUT
Analog Input 1
0 V 10 - GND
- 10V OUT
Analog Output 2
COM Digital outputs
Function
Programmable digital relay output - Default:
Ground shield cable reference
Programmable digital input - Default:
Programmable digital input - Default:
Programmable digital input - Default:
Programmable digital input - Default:
Programmable analog output - Default:
Programmable VOLTAGE analog input - Default: ±
Programmable CURRENT analog input - Default:
+ 10 V potential voltage reference
Programmable VOLTAGE analog input - Default:
0 V 10 reference for analog inputs/outputs
- 10 V potential voltage reference
Programmable analog output - Default:
Common reference for Digital outputs
[3] Motor running
[7] Freq sel 1
[8] Freq sel 2
[28] Stop (3wires)
[6] Jog
[0] Freq out abs
[0] 10V
[1] 0…20mA
[1] 0...10V
[0] Output curr
6mA @ +24V
-
+24V / 300mA
-
-
+50V / 50mA
6mA @ +24V
±10V / 5mA
±10V / 0.5mA
20mA
+10V / 10mA
±10V / 0.5mA
-
-10V/10mA
±10V / 5mA
-
LOAD
LOAD
Max
1A 30Vdc
1A 250Vac
-
Figure 5.3.2.1: Plug-in Terminal Strip Assignments
Maximum Cable Sizes for control terminals
Table 5.3.2.1: Maximum Permissible Cable Cross-section on the Plug-in Terminals of the Regulator Section
Maximum Permissible Cable Cross-Section Tightening
torque
flexible multi-core Nm (lbt. inch)
1 ... 34 0.5 … 1.5 (0.02…0.06) 0.5 ...1.5 (0.02…0.06) 28 …16 0.4 (35.4)TGy0160
AWGTerminals mm
2(inch)
The use of a 75 x 2.5 x 0.4 mm (3 x 0.1 x 0.02 inch) flat screwdriver is recommended. Remove 6.5 mm (0.26 inch) of theinsulation at the cable ends. Only one unprepared wire (without ferrule) should be connected to each terminal point.
Maximum Cable Length
Table 5.3.2.2: Maximum Control Cable Lengths
Cable section [mm2] 0.22 0.5 0.75 1 1.5
Max Length m [feet] 27 [88] 62 [203] 93 [305] 125 [410] 150 [492]avy3130
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 41
5.4 Serial Interface
5.4.1 In General
The RS 485 serial interface enables data transfer via a loop made of two symmetrical, twisted conductors with a commonshield. The maximum transmission distance is 1200 m (3936 feet) with a transfer rate of up to 38,400 KBaud. The transmissionis carried out via a differential signal. RS 485 interfaces are bus-compatible in half-duplex mode, i.e. sending and receivingtake place in sequence. Up to 31 ARTDriveG devices (up to 99 address selectable) can be networked together via the RS485 interface.
12345
9 8 7 6
150 R
TxA/RxATxB/RxB
0 V S
+5 V S
S3 S4
PE
RS485
XS
100
R
470
R
470
R
+5 V
S5
S6
Figure 5.4.1.1: RS485 Serial Interface
The RS 485 on the ARTDriveG series devices is located on the Regulation card in the form of a 9-pole SUB-D socketconnector (XS). The communication may be with or without galvanic isolation: when using galvanic isolation an externalpower supply is necessary (+5V).
Communication without galvanic isolation is suggested only in case of temporary connections for setup with one driveconnected. The differential signal is transferred via PIN 3 (TxA/RxA) and PIN 7 (TxB/RxB). Bus terminating resistors must beconnected at the physical beginning and end of an RS 485 bus in order to prevent signal reflection. The bus terminatingresistorson ARTDriveG drives are connected via jumpers S3 and S4. This enables a direct point-to-point connection with a PLC or PC.
NOTE! Ensure that only the first and last drop of an RS 485 bus have a bus terminating resistor (S3 and S4mounted). In all other cases (within the line) jumpers S3 and S4 must not be mounted.
A connection point to point (without galvanic isolation) can be done using “PCI-485” option interface (S5 and S6 mounted).
With S5 and S6 mounted the drive supply the serial line. This modality is allowed on point-to-point connection withoutgalvanic isolation only.
For multidrop connection (two or more drive), an external power supply is necessary (pin 5 / 0V and pin 9 / +5V).
Pins 6 and 8 are reserved for use with the “PCI-485” interface card.
When connecting the serial interface ensure that:
- only shielded cables are used
- power cables and control cables for contactors/relays are routed separately
NOTE! As for the connection of the serial line, make sure that the power cables and the cablescontrolling the contactors and the auxiliary relays are located into different panduits.
42 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
Serial protocol
The serial protocol is set via the “I.600 - Serial link cfg” parameter, which allows the selection of the following types:
proprietary protocol FoxLink, RTU Modbus (default) and Jbus.
The serial address is set via the “I.602 - Device address” parameter. Further details about the parameter transmission, theparameter type and the value range can be found in the tables of Chapter 7.1 (INTERFACE Menu / Serial Configuration). Forthe RTU Modbus Protocol see chapter 8.1 of this manual.
5.4.2 RS 485 Serial Interface Connector Description
On the AGy inverter, serial connection is available on connector XS (D-SUB type).
Table 5.4.2.1: Assignment of the XS Connector for the RS 485 Serial Interface
Designation Function I/O Elec. Interface
PIN 1 Internal use – –
PIN 2 Internal use – –
PIN 3 RxA/TxA I/O RS485
PIN 4 Internal use – –
PIN 5 0V (Ground for 5 V) – Power supply
PIN 6 Internal use – –
PIN 7 RxB/TxB I/O RS 485
PIN 8 Connected to ground – –
PIN 9 +5 V – Power supplyTGy0300
I = Input O = Output
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 43
5.5 Typical Connection Diagrams
5.5.1 AGy Connection
Figure 5.5.1.1: Connection through Terminals Strip, Typical Connection Diagram
M
18
Jog
F2
F1
4
5
6
22
23
24
25
7
Dig Input 7
Dig Input 8
Dig Input 1
Dig Input 2
Dig Input 3
Dig Input 4
Alarm Reset
COM-IN Dig Inputs
9
8
27
28
21
15
10
11
W1/L3
V1/L2
U2/T1U1/L1
PE2
FILTER
PE1
BRAKINGRESISTOR
Without Jumper,commandsare not functioning!
ENC B -
An Input 2
0...20 mA(or 4...20 mA)
Reverse
Run
Ext fault NO
NO
NC
CM
230/400/460V 3-phaseor
575V 3-phase
L1
+ 24V OUT
Dig Input 5
D C BR1
V2/T2
W2/T3
29
30
31
4k7 ohm
+ 10V OUT
0 V 10 - GND
26
33
31
32 -10V OUT
An Output 1
An Output 2
GND-A
±10 V (or 0-10 V)
20
19
1NO
NC
CM
3
2
Freq Sel 1Default
configuration
K1MF1
L1
L2
L3
Motor running
Dig Input 6
Stop (3wires)
An Input 3
An Input 1
±10 V Freq out abs
±10 V Output curr
0-10 V (or ±10 V)
Allarm state
0 V 24
0 V 24
Dig Output 4 - NO
Dig Output 3 - NO
GROUND REF 17
16
34 CM - OUT (terminal 11)
Open collector multi-functionoutputs:
Drive ready
Steady state
+24V (terminal 9)
Load
Load
Defaultconfiguration
Dig Output 1
Dig Output 2
COM Dig out
Dig Output 4 - COM
Digl Output 4 - NC
Dig Output 3 - COM
Dig Output 3 - NC
110V24
9+24V
Freq Sel 2
14ENC B +
13ENC A -
12ENC A +
36GND
35+5V / +8V
EXP-
ENC
-AG
Y(O
ptio
nca
rd)
EM
FEXT
FEXT
EMReserved
Reserved
NOTE! EM and FEXT terminals are available on sizes 3110 ... 5550 (230..480V) and are active on lift softwareonly.
NOTE! The connections indicated for command inputs represent the most common solution for an NPN typecommand. Other examples are given on the following figures.
44 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.5.2 Engineering Notes
Cables for analog reference and correction values should be screened (connection to the following terminals 25, 26, 27, 28,29, 30).
The screen should be on one side of the Inverter on terminal PE1. The same applies to the frequency signals for setting thereference value or feed back and for the connected speed and current displays (terminals 26, 33, 31).
Grounding the reference point
The reference point of shield cable for the control terminals must be normally grounded (to the terminal 21 in case of oneinverter).
Where several inverters are used in a single installation, their reference points of shield cable for the control terminalsshould be linked and grounded to the ground reference of the cabinet (with due attention to the minimum cable cross-section stated above).
Direct connection to PLC input/output sections
The following points should be noted when the control commands or reference values are taken directly from the input/output level of a programmable controller.
Grounding of the 0 V rail of a PLC is generally required. In this instance the reference points for the control commands onthe Inverter (terminals 10, 11) must not be grounded. To provide a high level of noise immunity, it is recommended that a0,1µF 250V DC capacitor be connected between terminals 10,11 and ground. Where an installation contains severalInverters, this measure should be taken on each Inverter.
Relay on the Inverter
To provide improved noise immunity, RC suppressors should be connected in parallel with the contactor coils, which areswitched onto the Inverter by one of the potential-free contacts.
Figure 5.5.1.2: Connections for PNP-type Controls - Connections for Controls Opto-insulated from the Inverter
9
4
23
5
24
6
25
22
7
8
10
11
REVERSAL
RUN
EXT FAULT
F1
F2
Stop (3wires)
JOG
RESET
+24
IN8
IN7
IN6
IN1
IN2
IN3
IN4
IN5
9
4
23
5
24
6
25
22
7
8
10
11
+24
IN8
IN7
IN6
IN1
IN2
IN3
IN4
IN5
CM-IN
GND-D
I
+
24V
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 45
5.5.3. Parallel Connection on the AC (Input) and DC (Intermediate Circuit) Side of SeveralInverters
Features and Limits:
- The inverters used have to be all the same size.
- AC input line chokes (see chapter 5.7.1) have to be the same (provided by the same supplier).
- The mains power supply has to be simultaneous for all inverters, i.e. a single switch /line contactor has to be used.
- Such connection is suitable for a maximum of 6 inverters.
- If necessary dissipate braking energy; a single internal braking unit (with external resistor) has to be used or one(or several) external braking unit (see manual: "BU32-...” , “BUy-...").
- Fast fuses (F12...F62) have to be fitted on the dc-link side ( C and D terminals) of each inverters (see chapter5.6.2).
Figure 5.5.3.1: Parallel Connection on the AC and DC Side of Several Inverters
M13
M23
M63
F11 L1
F21 L2
F61 L6
U
V
W
U2
V2
W2
C
D
INVERTER 1
U
V
W
U2
V2
W2
C
D
INVERTER 2
BR
F12
F22
F62
U
V
W
U2
V2
W2
C
D
INVERTER 6
BR
CR C
D
BU-32-...(B y-...)U
7 8 9 10
RBR
F7
RBR
L1
L2
L3
K1
M..3
F.. L..
U
V
W
U2
V2
W2
C
D
INVERTER ..
F..
(*)(*) Do not connect if external braking
units (BU32-.., BUy..) are used.Caution
46 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.6 Circuit Protection
5.6.1 External Fuses of the Power Section
The inverter must be fused on the AC Input side. Fuses, circuit breakers and slow protective switches can be used.Superfast semiconductor fuses provide a greater degree of protection.
NOTE! If the terminals of the DC Link circuit (C and D) are connected with external devices, semiconductor fusesmust always be fitted on the input side. This, for example, is the case with:
- connected external braking units (BU...)
- coupled DC Link circuits of several inverters
- connected external capacitors
Connections with three-phase inductance on AC input will improve the DC link capacitors life time.
Table 5.6.1.1: External Fuse Types for AC Input Side
Europe
1007
1015
1022 25000
1030 10000
2040 25000 GRD2/20 (F4D15) or Z14GR20 (F4M07) A70P20 FWP20 (S7G48)
2055 25000 GRD2/25 (F4D16) or Z14GR25 (F4M09) A70P25 FWP25 (S7G51)
2075 10000 GRD3/35 (F4D20) or Z22GR40 A70P35 FWP35 (S7G86)
3110 25000 GRD3/50 (F4D21) or Z22GR40 A70P40 FWP40 (S7G52)
3150 10000 GRD3/50 (F4D21) or Z22GR50 (F4M15) A70P40 FWP40 (S7G52)
4185 ... 82000 10000
1007 50000
1015 50000
1022 50000 A70P10 FWP10 (S7G49)
1030 50000
2040 50000
2055 50000 GRD2/20 (F4D15) or Z14GR20 (F4M07) A70P20 FWP20 (S7G48)
2075 50000 GRD2/25 (F4D16) or Z14GR25 (F4M09) A70P25 FWP25 (S7G51)
3110 50000 GRD3/50 (F4D21) or Z22GR40 A70P35 FWP35 (S7G86)
3150 50000 GRD3/50 (F4D21) or Z22GR50 (F4M15) A70P40 FWP40 (S7G52)
4185 30000
4220 25000
4300 25000 S00C+üf1/80/80A/660V or Z22gR80 A70P80 FWP80 (S7G54)
4370 25000 S00C+üf1/80/100A/660V or M00üf01/100A/660V (F4G18) A70P100 FWP100 (S7G55)
5450 25000
5550 25000
6750 25000
7900 25000
71100 25000
71320 25000
81600 25000
82000 25000 S2üf1/110/500A/660V or M2üf1/500A/660V ( ) A70P500 FWP500 (…)
2002 25000 (*)
2003 25000 (*)
2005 25000 (*) GRD2-16 (F4D14) A70P15 FWP15 (S848B)
3007 25000 (*) GRD2/25 (F4D16) or Z14GR25 (F4M09) A70P25 FWP25 (S7G51)
3010 25000 (*) Z14GR32 (F4M11) A70P30-1 FWP30A14F (S7I50)
3015 25000 (*) GRD3/50 (F4D21) or Z22GR54 (F4M13) A70P40 FWP40 (S7G52)
3020 25000 (*)
4025 50000
4030 50000
4040 50000 Z22GR63 (F4M17) A70P60-4 FWP60B (S7I34)
5050 50000 S00C+üf1/80/80A/660V (F4EAF) or Z22gR80 A70P80 FWP80 (S7G54)
5060 50000 S00C+üf1/80/100A/660V (F4EAG) or M00üf01/100A/660V A70P100 FWP100 (S7G55)
5075 50000 S00C+üf1/80/125A/660V F4EAJ) or M00üf01/125A/660V A70P125 FWP125 (S849B)
6100 50000 S00C+üf1/80/160A/660V (F4EAL) or M00üf01/160A/660V A70P150 (S7G56)
7125 50000 S1üf1/110/250A/660V or M1üf1/250A/660V (F4G28) A70P200 FWP200 (S7G58)
7150 50000 S1üf1/110/250A/660V or M1üf1/250A/660V (F4G28) A70P250 FWP250 (S7G59)
8200 50000 S2üf1/110/400A/660V or M2üf1/400A/660V (F4G34) A70P400 FWP400 (S7G62)agy0700gb
(*) 50000 [h] only with output choke
A70P400 FWP400 (S7G62)
FWP50 (S7G53)
FWP175 (S7G57)
S1üf1/110/250A/660V or M1üf1/250A/660V (F4G28) A70P300 FWP300 (S7G60)
For these types an external reactor is mandatory if the AC input impedence is equal or less than 1%
GRD2/16 (F4D14) or Z14GR16 (F4M05)
FWP10
GRD2/16 (F4D14) or Z14GR16 (F4M05)
A70P10 FWP10GRD2/10 (F4D13) or Z14GR10 (F4M03)
FWP20
Drive type
F1 - Fuses type (SIEI code)DC link capacitors life
time [h]
A70P20 FWP20
A70P10
Connections without three-phase reactor on AC input
25000
FWP10A14F
A70P50 FWP50 (S7G53)
(S7G49)GRD2/10 (F4D13) or Z14GR10 (F4M03)
GRD3/50 (F4D21) or Z22GR50 (F4M15)
A70P10
A70P20
S00C+üf1/80/160A/660V or M00üf01/160A/660V (F4E15) A70P175
GRD3/50 (F4D21) or Z22GR50 A70P50
S2üf1/110/400A/660V or M2üf1/400A/660V (F4G34)
AG
y..
.-5
(57
5V
)
America
AG
y..
.-4
(23
0V
...4
80
V)
Connections with and/or without three-phase reactor on AC input
(S7G48)
(S7G49)
(S7G48)
(S7G49)
GRD2/10 (F4D13) or Z14GR10 (F4M03)
Connections with three-phase reactor on AC input
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 47
Fuse manufacturers: Type GRD2... (E27), Z14... 14 x 51 mm, S00... ,S1... ,
Z22... 22 x 58 mm Jean Müller, Eltville
A70... Ferraz
FWP... Bussmann
NOTE! The technical data of the fuses, e.g. dimensions, weights, heat dissipation, auxiliary contactors, arereported in the corresponding data sheets.
5.6.2 External Fuses of the Power Section DC Input Side
Use the following fuses when a SR-32 Line Regen converter is used (see SR-32 instruction book for other details).
Table 5.6.2.1: External Fuses Type for DC Input Side
Fuses type SIEI code SIEI code
1007 Z14GR6 F4M01 A70P10 FWP10A14F S7G49
1015
1022
1030
2040
2055 Z14GR20 F4M07 A70P20-1 FWP20A14F S7G48
2075 Z14GR32 F4M11 A70P30-1 FWP30A14F S7I50
3110 Z14GR40 F4M13 A70P40-4 FWP40B S7G52
3150 Z22GR63 F4M17 A70P60-4 FWP60B S7I34
4185
4220
4300 S00C+/üf1/80/100A/660V F4EAG A70P100 FWP100 S7G55
4370 S00C+/üf1/80/125A/660V F4EAJ A70P150 FWP150 S7G56
5450 S00C+/üf1/80/160A/660V F4EAL A70P175 FWP175 S7G57
5550 S00üF1/80/200A/660V F4G23 A70P200 FWP200 S7G58
6750 S1üF1/110/250A/660V F4G28 A70P250 FWP250 S7G59
7900 S1üF1/110/315A/660V F4G30 A70P350 FWP350 S7G61
71100 S1üF1/110/400A/660V F4G34 A70P400 FWP400 S7G62
71320
81600
82000 S1üF1/110/600A/660V A70P600 FWP600 S7G65
Fuses type SIEI code SIEI code
2002 - A100P15 - S85A0
2003 - A100P15 - S85A0
2005 - A100P20 - S85A1
3007 - A100P30 - S85A2
3010 - A100P35 FWJ35 S85A3
3015 - A100P50 FWJ50 S85A4
3020 - A100P60 FWJ60 S85A5
4025 - A100P60 FWJ60 S85A5
4030 - A100P70 FWJ70 S85A6
4040 - A100P80 FWJ80 S85A7
4050 - A100P100 FWJ100 S85A8
5060 - A100P125 FWJ125 S85A9
5075 - A100P150 FWJ150 S85B0
7100 - A100P200 FWJ200 S85B1
7125 - A100P250 FWJ250 S85B2
7150 - A100P250 FWJ250 S85B2
8200 - A100P400 FWJ400 S85B4agy0701gb
AG
y..
.-5
(575V
)
Fuses type
Fuses type
AG
y..
.-4
(230V
...4
80V
)
Europe AmericaDrive type
S7G48Z14GR16 A70P20-1 FWP20A14FF4M05
Drive typeEurope America
Z14GR10 S7G49A70P10 FWP10A14FF4M03
S7G63
S7G54S00C+/üf1/80/80A/660V F4EAF A70P80 FWP80
S1üF1/110/500A/660V F4E30 A70P500 FWP500
Fuse manufacturers: Type Z14..., Z22, S00..., S1... Jean Müller, Eltville
A70P..., A100P... Ferraz
FWP... Bussmann
NOTE! The technical data of the fuses, e.g. dimensions, weights, heat dissipation, auxiliary contactors, arereported in the corresponding data sheets.
48 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.6.3 Internal Fuses
Table 5.6.3.1: Internal Fuses
Drive type Designation Protection of Fuse (source) Fitted on:
Power card PV33-4
Power card PV33-5
7900...82000 F3 Fans transformer
2.5A 6.3x32
(Bussmann: MDL 2.5, Gould
Shawmut: GDL1-1/2, Siba: 70 059
76.2,5 , Schurter: 0034.5233)
Bottom cover
(power terminals side)
Power card PV33-4N
Power card PV33-5N
7125...8200 F3 Fans transformer
2.5A 6.3x32
(Bussmann: MDL 2.5, Gould
Shawmut: GDL1-1/2, Siba: 70 059
76.2,5 , Schurter: 0034.5233)
Bottom cover
(power terminals side)
agy0702gb
AG
y...-
4(2
30V
...4
80V
)
4025...8200
2A fast 5 x 20 mm (Bussmann:
SF523220 or Schurter:
FSF0034.1519 or Littlefuse:
217002)
+24VF1
AG
y...-
5(5
75V
)
2A fast 5 x 20 mm
(Bussmann: SF523220 or
Schurter: FSF0034.1519 or
Littlefuse: 217002)
4185...82000 F1 +24V
5.7 Chokes / Filters (Optional)
NOTE! A three-phase inductance should be connected on the AC Input side in order to limit the input RMScurrent of AGy series Drives. The inductance can be provided by an AC Input choke or an AC Inputtransformer.
NOTE! For the use of output sinusoidal filters, please contact the nearest SIEI office.
Figure 5.7.1: Input / output chokes dimensions
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 49
5.7.1 AC Input Chokes
Table 5.7.1.1: 3-Phase AC Input Chokes
Mains
inductance
Rated
current
Saturation
current
Freq.
[mH] [A] [A] [Hz] a b c D1 E1
1007 6.1 2.5 5 50/60 LR3y-1007 S7AAD
1015 3.69 3.7 7.4 50/60 LR3y-1015 S7AAE
1022 2.71 5.5 11 50/60 LR3y-1022 S7AAF
1030 2.3 6.7 14 50/60 LR3y-1030 S7AB3
2040 1.63 8.7 18 50/60 LR3y-2040 S7AAG 2 (4.4)
2055 1.29 11.8 24.5 50/60 LR3y-2055 S7AB5 2.2 (4.4) 120 (4.7) 125 (4.9) 75 (2.6) 100 (3.9) 55 (2.2)
2075 0.89 17.4 36.5 50/60 LR3y-2075 S7AB6 4.9 (10.8) 150 (5.9) 155 (6.1) 79 (3.1) 90 (3.5) 54 (2.1)
3110 0.68 22.4 46.5 50/60 LR3y-3110 S7AB7 5 (11) 150 (5.9) 155 (6.1) 79 (3.1) 90 (3.5) 54 (2.1)
3150 0.51 30 61 50/60 LR3y-3150 S7AB8 6.2 (13.7) 150 (5.9) 168 (6.6) 100 (3.9) 90 (3.5) 69 (2.7)
4185 0.35 41 83 50/60
4220 0.35 41 83 50/60
4300 0.24 58 120 50/60 LR3-030 S7FF3 9.5 (20.9) 180 (7.1) 160 (6.3) 170 (6.7) 150 (5.9) 80 (3.1)
4370 0.18 71 145 50/60 LR3-037 S7FF2 9.5 (20.9) 180 (7.1) 160 (6.3) 180 (7.1) 150 (5.9) 80 (3.1)
5450 0.13 102 212 50/60
5550 0.13 102 212 50/60
6750 0.148 173 350 50/60
7900 0.148 173 350 50/60
71100 0.085 297 600 50/60
71320 0.085 297 600 50/60
81600 0.085 297 600 50/60
82000 0.085 380 710 50/60 LR3-200 S7AE9 54 (119) 300 (11.8) 270 (10.6) 355 (13.9) 250 (9.8) 130 (5.1)
2002 4.5 4.2 8.4 50/60 LR3y-5-002 S7AD0 2 (4.4) 120 (4.7) 125 (4.9) 75 (2.6) 100 (3.9) 42 (1.6)
2003 3.8 5.2 10.4 50/60 LR3y-5-003 S7AD2 2 (4.4) 120 (4.7) 125 (4.9) 75 (2.6) 100 (3.9) 42 (1.6)
2005 2.3 8.1 16.2 50/60 LR3y-5-005 S7AD3 2.7 (6) 120 (4.7) 125 (4.9) 85 (3.3) 100 (3.9) 52 (2)
3007 1.5 12.9 25.8 50/60 LR3y-5-007 S7AC7 5 (11) 150 (5.9) 152 (6) 80 (3.1) 90 (3.5) 55 (2.2)
3010 1.2 16.5 33.0 50/60 LR3y-5-010 S7AC8 5 (11) 150 (5.9) 152 (6) 80 (3.1) 90 (3.5) 55 (2.2)
3015 0.9 21.8 43.6 50/60 LR3y-5-015 S7AC9 5.5 (12.1) 150 (5.9) 164 (6.4) 96 (3.8) 90 (3.5) 60 (2.4)
3020 0.7 28.5 57 50/60 LR3y-5-020 S7AD1 6.2 (13.7) 150 (5.9) 164 (6.4) 106 (4.2) 90 (3.5) 70 (2.8)agy0703gb
120 (4.7)LR3-160 S7D40 44 (97.0) 300 (11.8) 270 (10.6) 260 (10.2) 250 (9.8)
AG
y..
.-5
(57
5V
)A
Gy
...-
4(2
30
V..
.48
0V
)
Drive
type
LR3-055
LR3-090
Three-phases main chokes
80 (3.1)
85 (3.3)
ModelWeight
kg (lbs)
12.5 (27.6)
55 (121.3)
SIEI code
S7FF1
S7D19
1.8 (3.9)
1.9 (4.2)
215 (8.5) 180 (7.1)
Dimensions : mm (inch)
120 (4.72) 125 (4.92) 65 (2.56) 100 (3.94) 45 (1.77)
240 (9.4) 150 (5.9)
300 (11.8) 265 (10.4) 210 (8.3) 250 (9.8)
LR3-022 S7FF4 7.8 (17.2) 180 (7.1) 182 (7.2) 130 (5.1) 150 (5.9) 70 (2.8)
For sizes up to 20Hp, an input choke is strongly reccomended in order to:
- prolong the life time of the DC link capacitors and the reliability of the input rectifier.
- reduce the AC line harmonic distortion
- reduce problems due to low impedence AC line (≤ 1%).
NOTE! The current rating of these chokes (reactors) is based on nominal current of standard motors, listed intable 3.3.4.1 in section 3.3.4, “AC Output”.
NOTE! The 4025 … 8200 sizes of AGy-5 series (575Vac), integrate as standard the input choke on intermediatecircuit (DC-Link). With this configuration the three phase input choke it is NOT required.
5.7.2 Output Chokes
The AGy Drive can be used with general purpose standard motors or with motors specially designed for Drive use. The latterusually have a higher isolation rating to better withstand PWM voltage.
Motors designed for use with Adjustable Frequency Drives do not require any specific filtering of the voltage waveform fromthe Drive. For general purpose motors and using drives up to 2005 size, especially with long cable runs (typically over 100m [328 feet]) an output choke is recommended to mantain the voltage waveform within the specified limits. Suggestedchoke ratings and part numbers are listed in table 5.7.2.1.
The rated current of the filters should be approx. 20% above the rated current of the frequency Drive in order to take intoaccount additional losses due to PWM waveform.
50 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
Table 5.7.2.1: Recommended Values for Output Chokes
Drive type
Mains
inductance
Rated
current
Saturation
current Model
[mH] [A] [A] a b c D1 E1
1007
1015
1022
1030
2040
2055
2075
3110
3150 0.43 32 68 LU3-015 S7FM2 7.5 (16.5) 180 (7.1) 160 (6.3) 170 (6.7) 150 (5.9) 70 (2.8)
4185
4220
4300 0.24 58 100 LU3-030 S7FH4 9.5 (20.9) 180 (7.1) 160 (6.3) 180 (7.1) 150 (5.9) 80 (3.1)
4370 0.18 76 130 LU3-037 S7FH5 9.7 (21.4) 180 (7.1) 160 (6.3) 180 (7.1) 150 (5.9) 80 (3.1)
5450
5550
6750
7900
71100
71320
81600
82000 LU3-200
2002
2003
2005 1.9 7 13 LU3-5-005 S7FI3 2 (4.4) 120 (4.7) 125 (4.9) 75 (2.6) 100 (3.9) 42 (1.6)
3007
3010
3015
3020
4025 0.51 30 54.9 LU3-5-025 S7FI6 6.2 (13.7) 150 (5.9) 164 (6.4) 106 (4.2) 90 (3.5) 70 (2.8)
4030 0.43 36 65.9 LU3-5-030 S7FI7 6.8 (15) 180 (7.1) 182 (7.2) 122 (4.8) 150 (5.9) 64 (2.5)
4040 0.34 46 84.2 LU3-5-040 S7FI8 10 (22) 180 (7.1) 165 (6.5) 170 (6.7) 150 (5.9) 84 (3.3)
4050 0.27 58 106.1 LU3-5-050 S7FI9 12 (26.5) 180 (7.1) 165 (6.5) 170 (6.7) 150 (5.9) 84 (3.3)
5060 0.22 69 126.3 LU3-5-060 S7FL0 12 (26.5) 180 (7.1) 165 (6.5) 170 (6.7) 150 (5.9) 84 (3.3)
5075 0.18 86 157.4 LU3-5-075 S7FL1 12 (26.5) 180 (7.1) 165 (6.5) 170 (6.7) 150 (5.9) 84 (3.3)
6100 0.14 109 200 LU3-5-100 S7FL4
7125 0.11 158 290 LU3-5-150 S7FL5
7150 0.11 158 290 LU3-5-150 S7FL5
8200 0.070 220 403 LU3-5-200 S7FL6agy0704gb
AG
y...-
5(5
75V
)
120 (4.7) 125 (4.9)3 4.5
Please contact the nearest SIEI office
90 (3.5) 55 (2.2)
0.64 24,2 44.3 LU3-5-020 106 (4.2) 90 (3.5)
80 (3.1)
70 (2.8)S7FI5 6.2 (13.7) 150 (5.9) 164 (6.4)
S7FI4 5 (11) 150 (5.9) 152 (6)1 13,8 25.3 LU3-5-010
8.5 LU3-5-003 S7FI2 2 (4.4)
260 (10.2) 240 (9.4)
75 (2.6) 100 (3.9)
Please contact the nearest SIEI office
27.5 (60.6) 300 (11.8)
42 (1.6)
200 (7.9) 80 (3.1)
250 (9.8) 90 (3.5)
18.5 (40.8) 240 (9.4) 210 (8.3) 200 (7.9)
150 (5.9)
150 (5.9)
14 (30.9) 240 (9.4) 210 (8.3) 180 (7.1) 200 (7.9)
8 (17.6)
180 (7.1)5.8 (12.8) 110 (4.3)
180 (7.1)
170 (6.7)
180 (7.1) 130 (5.1)
5.2 (11.5) 180 (7.1) 110 (4.3) 150 (5.9)170 (6.7)
80 (3.1)
60 (2.4)
60 (2.4)
70 (2.8)S7FG4
S7FH6
310
AG
y...-
4(2
30V
...4
80V
)
LU3-090
LU3-055
1.4 9.5 20
0.87 16 34
LU3-011
LU3-005
0.041 310 540
S7FH7180
LU3-160 S7FH8
0.12 110 192
0.07
Three-phases choke
0.51 27 57
SIEI code
S7FG2
S7FG3
LU3-003
Weight
kg (lbs)
Dimensions : mm (inch)
0.33 42 72 LU3-022 170 (6.3) 150 (5.9) 70 (2.8)S7FH3 8 (17.6) 180 (7.1) 160 (6.3)
NOTE! When the Drive is operated at the rated current and at 50 Hz, the output chokes cause a voltage dropof approx. 2% of the output voltage.
5.7.3 Interference Suppression Filters
The inverters of AGy series must be equipped with an external EMI filter in order to reduce the radiofrequency emissions onthe mains line. The filter selection is depending on the drive size and the installation environment. For this purpose see the“EMC Guidelines” instruction book.
In the Guide it is also indicated how to install the cabinet (connection of filter and mains reactors, cable shield, groundig,etc.) in order to make it EMC compliant according the EMC Directive 89/336/EEC.
The document describes the present situation concerning the EMC standards and the compliance tests made on the SIEIdrives.
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 51
Table 5.7.3.1: EMI filters
a b c d D1 E1 R P M
1007...1030 (**) EMI FFP 480-9 S7DEQ 1.1 (2.4) 375 (14.8) 104 (4.1) 45 (1.8) - 360 (14.2) 59 (2.3) - M5 Ø6
2040...2075 (**) EMI FFP 480-24 S7DER 1.4 (3.1) 375 (14.8) 150 (5.9) 45 (1.8) - 360 (14.2) 105 (4.1) - M5 Ø6
3110 (**) EMI FFP 480-30 S7DES 1.6 (3.5) 390 (15.4) 200 (7.9) 45 (1.8) - 375 (14.8) 155 (6.1) - M5 Ø6
3150 (**) EMI FFP 480-40 S7DET 2.3 (5.1) 390 (15.4) 200 (7.9) 45 (1.8) - 375 (14.8) 155 (6.1) - M5 Ø6
4185…4220 (**) EMI 480-45 S7DFU 1.3 [2.9] 250 [9.8] 85 [3.3] 90 [3.5] - 235 [9.3] 60 [2.4] - - M6
4300...4370 (**) EMI 480-70 S7DFZ 2.6 [5.7] 270 [10.6] 90 [3.5] 150 [5.9] - 255 [10.0] 65 [2.6] - - M6
5450...5550 (**) EMI 480-100 S7DGA 2.6 [5.7] 270 [10.6] 90 [3.5] 150 [5.9] - 255 [10.0] 65 [2.6] - - M6
6750 (**) EMI 480-150 S7DGB 4.4 [9.7] 400 [15.7] 120 [4.7] 170 [6.7] - 365 [14.4] 102 [4.0] - - M6
7900 (**) EMI 480-180 S7DGC 4.4 [9.7] 400 [15.7] 120 [4.7] 170 [6.7] - 365 [14.4] 102 [4.0] - - M6
71100...71320 (**) EMI 520-280 S7DEL 28 (61.7) 700 (27.6) 260 (10.2) 130 (5.1) 530 (20.9) 660 (26.0) 220 (8.7) - M10 Ø9
81600 (**) EMI 520-450 S7DEM 45 (99.2) 700 (27.6) 300 (11.8) 150 (5.9) 250 (9.8) 200 (7.9) 280(11.0) - M16 Ø9
82000 (**) EMI 520-450 S7DEM 45 (99.2) 700 (27.6) 300 (11.8) 150 (5.9) 250 (9.8) 200 (7.9) 280(11.0) - M16 Ø9
1007...1030 (**) EMI FFP 480-9 S7DEQ 1.1 (2.4) 375 (14.8) 104 (4.1) 45 (1.8) - 360 (14.2) 59 (2.3) - M5 Ø6
2040...2075 (**) EMI FFP 480-24 S7DER 1.4 (3.1) 375 (14.8) 150 (5.9) 45 (1.8) - 360 (14.2) 105 (4.1) - M5 Ø6
3110 (**) EMI FFP 480-30 S7DES 1.6 (3.5) 390 (15.4) 200 (7.9) 45 (1.8) - 375 (14.8) 155 (6.1) - M5 Ø6
3150 (**) EMI FFP 480-40 S7DET 2.3 (5.1) 390 (15.4) 200 (7.9) 45 (1.8) - 375 (14.8) 155 (6.1) - M5 Ø6
4185...4220 (**) EMI 480-45 S7DFU 1.3 [2.9] 250 [9.8] 85 [3.3] 90 [3.5] - 235 [9.3] 60 [2.4] - - M6
4300 (**) EMI 480-55 S7DFV 2 [4.4] 250 [9.8] 85 [3.3] 90 [3.5] - 235 [9.3] 60 [2.4] - - M6
4370 (**) EMI 480-70 S7DFZ 2.6 [5.7] 270 [10.6] 90 [3.5] 150 [5.9] - 255 [10.0] 65 [2.6] - - M6
5450...5550 (**) EMI 480-100 S7DGA 2.6 [5.7] 270 [10.6] 90 [3.5] 150 [5.9] - 255 [10.0] 65 [2.6] - - M6
6750...7900 (**) EMI 480-150 S7DGB 4.4 [9.7] 400 [15.7] 120 [4.7] 170 [6.7] - 365 [14.4] 102 [4.0] - - M6
71100 (**) EMI 480-180 S7DGC 4.4 [9.7] 400 [15.7] 120 [4.7] 170 [6.7] - 365 [14.4] 102 [4.0] - - M6
71320 (**) EMI 520-280 S7DEL 28 (61.7) 700 (27.6) 260 (10.2) 130 (5.1) 530 (20.9) 660 (26.0) 220 (8.7) - M10 Ø9
81600 (**) EMI 520-280 S7DEL 28 (61.7) 700 (27.6) 260 (10.2) 130 (5.1) 530 (20.9) 660 (26.0) 220 (8.7) - M10 Ø9
82000 (**) EMI 480-400 S7DGI
2055
2075 95 [3.7] M5
3110
(**): EN61800-3, 1st environment restricted distribution. agy0710gb
AG
y..
.-4
(48
0V
)SIEI codeDrive type Class Model
4.5x3A S7DFA 0.96 [2.1] 105 [4.1]
AG
y..
.-4
(23
0V
...4
80
V)
Weight
kg (lbs)
Dimensions : mm (inch)A
Gy
...-
4(2
30
V..
.40
0V
)
100 [3.9] 57 [2.2]
EMI-C 480-25
For drive/motor
cable 5 meters
max length.
57 [2.2]
Please contact the nearest SIEI office
Figure 5.7.3.1: Filters dimension
D1
E1b
LIN
E
LO
AD
a
c
M
P
EMI 480-36 , EMI 520-8/19, EMI 600-...EMI FFP ...
c
M4
M5
Wires 2.5 mm block2
LOADL1 L2 L3
LINE
L1 L2 L3P1
D1
b20
0±20
200±
20E1
4.5x3
a
a
b
c
D1
E1
M
Pd
EMI 520-280
EMI-C 480-25
EMI 600-8/18=4mmEMI 600-34/47=10EMI 600-62/85=25EMI 600-113/145=50EMI 600-205=95
2
mmmm
mmmm
2
2
2
2
EMI 600-8/18=AWG16EMI 600-34=AWG10EMI 600-47=AWG8EMI 600-62=AWG6EMI 600-205=50mm2
d R (*)
b
c
a
D1
E1
M
P
(*)EMI 600-85
113145
terminal blockconnections
EMI 600-EMI 600-
a
c
D1
E1M
b
EMI 480-45...180
52 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.7.3.1 EMI filter connections for Sizes 1007...3150 (230V...480V)
ACPowerSupply
Cabinet Mounting panelAC Drive
AC
Mains
choke
GroundBus
Motor
cable
terminals
AC Motor
EMI filter
U1 V1 W1 U2 V2 W2 PE2 PE1
AC Mains
ContactorAC fuses
Outputreactor
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 53
5.7.3.2 EMI filter connections for Sizes 4185...82000 (230V...480V)
Supply Cabinet Mounting panelInverter
Line
reactor
EMI-FN
filter
Ground
Bus
Motor cable
terminals
Motor
U, V, W
PE
U2, V2, W2 PE
Output
reactor
54 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
Warning!
5.8 Braking in the AGy System
Two means of braking are possible:
- Internal Braking Unit
- Injection of direct current from the Inverter into the motor (D.C. braking)
There are two essential differences between the two braking methods:
- A braking unit can be used for speed reduction (e.g.: from 1000 to 800 rpm), whereas D.C. braking can only be used forbraking to standstill.
- The energy in the drive is converted into heat in both cases. This conversion takes place in a braking resistor encasedin the braking unit. With D.C. braking, the energy is converted into heat in the motor itself, resulting in a further rise inmotor temperature.
5.8.1 Braking Unit
In oversynchronous or regenerative operation, the frequency-controlled three-phase motor feeds energy back to the DClink circuit via the Drive. This leads to an increase in the intermediate circuit voltage. Braking units (BU) are therefore usedin order to prevent the DC voltage rising to an impermissible value. When used, these activate a braking resistor that isconnected in parallel to the capacitors of the intermediate circuit. The feedback energy is converted to heat via the brakingresistor (R
BR), thus providing very short deceleration times and restricted four-quadrant operation.
Figure 5.8.1: Operation with Braking Unit (Principle)
E
3M
_ R BR
BU
UZK
Drive sizes 1007 up to 3150 (230V...480V) and 2002 up to 3020 (575V) have as standard an internal braking unit.
Drive sizes 4185 up to 5550 (230V...480V) and 4025 up to 5075 (575V) can be equipped with an internal braking unit (seesection 3.1.2, Inverter type designation) factory mounted on request.
All the standard AGy... drive can be equipped with an external braking unit (BU-32...) connected to the terminals C and D.
The braking resistor is optional and has always to be mounted externally.
NOTE! When the circuit terminals C and D are connected to external devices, the AC Input must be protectedwith superfast semiconductor fuses! Observe the mounting instruction concerned.
The braking resistors can be subject to unforeseen overloads due to possible failures.
The resistors have to be protected using thermal protection devices. Such devices do not have tointerrupt the circuit where the resistor is inserted but their auxiliary contact must interrupt the powersupply of the drive power section. In case the resistor foresees the precence of a protection contact,such contact has to be used together with the one belonging to the thermal protection device.
The braking threshold for the internal braking unit is dependent on the value of the supply voltage of the drive.
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 55
Table 5.8.1.1: Braking Thresholds for Different Mains
Mains voltage Braking threshold
VBR [V]
220 Vac 390 Vdc
380 Vac 760 Vdc
460 Vac 760 Vdc
575 Vac 965 Vdcagy0705
Table 5.8.1.2: Technical Data of the Internal Braking Units
Inverter Minimum
type IRMS IPK T RBR
[A] [A] [s] [ohm]
1007 … 2040 4.1 7.8 19 100
2055 … 2055 6.6 12 16 67
3110 12 22 17 36
3150 17 31 16 26
4185 - 4220 18 52 42 15
4300 37 23
4370 29 37
5450 … 5550 50 104 22 7.5
6750 … 82000
2002
2003
2005
3007
3010
3015 5.8 13 17 74
3020 10.3 23 16 42
4025 19 42 42 23
4030 19 42 23 23
4040 24 54 37 18
5050 24 54 37 18
5060 37 84 22 11,6
5075 37 84 22 11,6
6100 … 8200agy0706gb
External braking unit (optional)
AG
y…
-5(5
75
V) 4.4 9.7 16 100
3.1 6.9 19 140
AG
y…
-4(2
30
V…
48
0V
)
External braking unit (optional)
78 10
IRMS : Nominal current of the braking unit
IPK : Peak current deliverable for 60 seconds max.
T : Minimum cycle time for a working at IPK for 10 seconds
56 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
5.8.1.1 External Braking Resistor
Recommended resistors for use with internal braking unit:
Table 5.8.1.3: Lists and Technical Data of the External Standard Resistors
Drive PNBR RBR EBR Resistor
Type [kW] [Ohm] [kJ] Type a b c a1 b1
1007 ... 2040 0.6 100 22 MRI/T600 100R S8SS3 1.5 (3.3) 320 (12.6) 120 (4.7) 100 (3.9) 360 (14.2)
2055 ... 2075 0.9 68 33 MRI/T900 68R S8SS2 2.7 (6.0) 320 (12.6) 160 (6.3) 120 (4.7) 380 (15.0)
3110 1.3 49 48 MRI/T1300 49R S8ST4 3.7 (8.2) 320 (12.6) 320 (12.6) 120 (4.7) 380 (15.0)
3150 2.1 28 90 BR T2K0-28R S8T00F 5.4 (9.7) 498 (19.6) 100 (3.9) 250 (9.8) 478 (18.8) 40 (1.6)
4185 ... 4220 4 15.4 180 BR T4K0-15R4 S8T00G 7.0 (15.4) 625 (24.6) 100 (3.9) 250 (9.8) 605 (23.8) 40 (1.6)
4300 ... 4370 4 11.6 180 BR T4K0-11R6 S8T00H 7.0 (15.4) 625 (24.6) 100 (3.9) 250 (9.8) 605 (23.8) 40 (1.6)
5450 ... 5550 8 7.7 360 BR T8K0-7R7 S8T00I 11.5 (25.) 625 (24.6) 160 (6.3) 250 (9.8) 605 (23.8) 60 (2.4)
2002 ... 2005 0.6 140 22 MRI/T600 140R S8SY7 1.5 (3.3) 320 (12.6) 120 (4.7) 100 (3.9) 360 (14.2)
3007 ... 3010 0.9 100 33 MRI/T900 100R S8SY8 2.7 (6.0) 320 (12.6) 160 (6.3) 120 (4.7) 380 (15.0)
3015 1.3 74 48 MRI/T1300 74R S8SY9 3.7 (8.2) 320 (12.6) 205 (8.7) 120 (4.7) 380 (15.0)
3020 2.1 42 90 BR T2K0-42R S8T00M 5.4 (9.7) 498 (19.6) 100 (3.9) 250 (9.8) 478 (18.8) 40 (1.6)
4025 ... 4030 4 23 180 BR T4K0-23R S8T00N 7.0 (15.4) 625 (24.6) 100 (3.9) 250 (9.8) 605 (23.8) 40 (1.6)
4040 ... 4050 4 18 180 BR T4K0-18R S8T00O 7.0 (15.4) 625 (24.6) 100 (3.9) 250 (9.8) 605 (23.8) 40 (1.6)
5060 ... 5075 8 11.6 180 BR T8K0-11R6 S8T00R 11.5 (25.) 625 (24.6) 160 (6.3) 250 (9.8) 605 (23.8) 60 (2.4)
agy0707
AG
y...-
5(5
75V
)
Weight
kg (lbs)
Dimensions : mm (inch)SIEI code
AG
y...-
4(2
30V
...4
80V
)
Figure 5.8.2: External resistors
a
b
C
a1
MRI/T600...,/T900...,/T1300…
BR T2K0..., BR T8K0...
a
c
BR T2K0: PG 11/PG16
b
BR T4K0: PG 13
BR T8K0: PG 16
PG 7: on version withThermostat only
a
b1
c
13x6.5
b
a1
b1
=
=
PG 11 PG 7
* PG7 on versionwith thermostat only
BR T12K0...
Parameters description:
PNBR Nominal power of the braking resistor
RBR Braking resistor value
EBR Max surge energy which can be dissipated by the resistor
PPBR Peak power applied to the braking resistor
TBRL Maximum braking time in condition of limit operating cycle (braking power = PPBR with typicaltriangular profile)
T = 2 = [s]BRL
EBR
PPBR
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 57
Figure 5.8.3: Limit Operating Braking Cycle with Typical Triangular Power Profile
TCL
n,P
PPBR
TBRL
n
EBR
t
TCL Minimum cycle time in condition of limit operating cycle (braking power = PPBR with typical triangular
profile)
T = T = [s]CL BRL
P
PPBR
NBR
12
Resistor model: Standard resistor data
Example code: MRI/T900 68R
MRI = resistor type
900 = nominal power (900 W)
T= with safety thermostat
68R = resistor value (68 Ω)
NOTE! The suggested match of resistor-model and inverter-size, allows a braking stop at nominal torque withduty cycle TBR / TC = 20%
Where: TBR = Braking time
TC = Cycle time
Figure 5.8.4: Braking cycle with TBR / TC = 20%
TC
P,n
TBR
n
t
The standard resistor can be used for couplings, different from the ones above reported.
These resistors, whose technical data are reported in the table 5.8.1.3, have been dimensioned to tolerate an overload equalto 4 time their nominal power for 10 seconds. In any event they can tolerate also an overload, whose energetic dissipationwas the same of the maximum power level defined by:
P =PB R
V [V]B R
2
R [ohm]BR
=[w]
58 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
Where: VBR = braking unit threshold (see table 5.8.1.1)
With reference to the figure 5.8.5, where the power profile is the typical triangular one, the following example can be takeninto consideration (see also table 5.8.1.3).
Resistor model: MRI/T600 100R
Nominal power PNBR = 600 [W]
Maximum energy EBR = 4 x 600[W] x 10[s] = 24000[J]
Inverter mains supply = 460V
From table 5.8.1.1: VBR =780V
T BRL =2E BR
P PBR
=24000
6084=7.8[s]2P PBR =
V BR
R BR
2
=780
100
2
=6084 [W]
It is necessary to consider the following relation:
A) If TBR ≤ EBR / PNBR verify:
1) PMB ≤≤≤≤≤ 2 . EBR / TBRWhere: PMB is the average power of the cycle (see.fig. 5.8.5)
2)P x T
2TMB BR
C
PNBR
The average power of the cycle must not be higher than the nominal power of the resistor.
B) If TBR > EBR / PNBR that is to say, in case of very long braking time, it must be dimensioned PMB ≤ PNBR
Figure 5.8.5: Generic braking cycle with triangular profile
TC
n,P
PPBR
TBR t
PMB
If one of the above mentioned rules is not respected, it is necessary to increase the nominal power of the resistor, respectingthe limit of the internal braking unit (reported in table 5.8.1.2).
The table 5.8.1.2 can be used to choose an external resistor, different from the standard series. Generally the followingcondition must be satisfed
I R M S1 P TPB R B R
R TB R C2
In case of using more external BUs, each BU with a resistor (all the same) refers to the parameters calculation of a single unit.
ARTDriveG Instruction manual Chapter 5 - Wiring Procedure • 59
Caution
5.8.2 D.C. Braking
The Inverter offers the facility of D.C. braking as a standard. To this end, the Inverter injects D.C. current into two motorphases, thereby generating braking torque. The kinetic energy of the machine is dissipated as heat in the motor.
This option enables the drive to be braked to a standstill. It does not permit deceleration to a lowerspeed. It may be necessary to measure the braking current in the “U” phase.
M3 ~M
3 ~Energy Machine
Energy
UDC
_
+
Inverter
UVW
/2
Figure 5.8.7: D.C. Braking, Schematic
5.9 Discharge Time of the DC-Link
Table 5.9.1: DC Link Discharge Times
Type I2N Time (seconds) Type I2N Time (seconds)
1007 2.1 2002 3.8
1015 3.5 2003 4.5
1022 4.9 2005 7.0 200
1030 6.5 3007 10.8
2040 8.3 3010 13.8
2055 12.1 3015 18.7
2075 15.4 3020 24.2
3110 23.1 4025 30 230
3150 29.7 4030 36 230
4185 34 4040 46 230
4220 41 4050 58 300
4300 55 5060 69 300
4370 69 90 5075 86 300
5450 81 6100 109 300
5550 99 7125 137 300
6750 124 7150 158 300
7900 161 8200 218 300
71100 183
71320 218
81600 282
82000 348agy0708gb
220
60
100
250
AG
y..
.-4
(23
0V
...4
80
V)
Ag
y..
.-5
(57
5V
)
120
90
150
205
This is the minimum time that must be elapsed since an AGy Drive is disconnected from the AC Input before an operatormay service parts inside the Drive to avoid electric shock hazard.
CONDITION: These values consider a turn off for a Drive supplied at 480Vac +10%, without any option, ( the chargefor the switching supply is the regulation card, the keypad and the 24Vdc fans “if mounted”).
The Drive is disabled. This represents the worst case condition.
60 • Chapter 5 - Wiring Procedure ARTDriveG Instruction manual
Caution
Chapter 6 - Drive Keypad Operation
In this chapter the parameters management is described, by using the drive keypad.
The following examples show some procedures with the two different keypads, KBG-1 (7 segments display) and KBG-LCD(alphanumeric LCD display). The procedures of parameters setting will be the same for both keypad types. The displayingof parameters will be different, in accordance with the keypad model mounted on the drive.
6.1 Keypad
Changes made to parameter have immediate effect on drive operation, but are not automatically storedin permanent memory. An explicit command is required to permanently store the parameters:
"C.000 - Save parameters" and confirming with Enter.
Res
et
Nav
igat
ion
Hz A VPrg Rev Fwd
Prg
E
Prg Scroll menu: Allows navigation thruogj the drive main menu (d.xxx, S.xxx, I.xxx, F.xxx, P.xxx, A.xxx andC.xxx). Also used to exit the editing mode of a parameter without appling the changes.
E Enter button: Used to enter the editing mode of the selected parameter or to confirm the value.
UP button: Used to scroll up through parameters or to increase numeric values while in editing mode; it canalso be used to increase motorpotentiometer reference value, when "F.000-Motorpot ref" parameteris displayed
(F, FREQ RAMP menu).
DOWN button: Used to scroll down through parameters or to decrease numeric values while in editing mode; it canalso be used to decrease motorpotentiometer reference values, when "F.000-Motorpot ref" parameteris displayed (F, FREQ RAMP menu).
I Start button: Used to START the drive via keypad;
"S.200-Cms source sel = [0] Keypad" parameter setting and +24V between 5 & 8 terminals arealways required to initiate a start command from Keypad.
O Stop button: Used to STOP the drive via keypad;
The action of the Stop key can be programmed by the parameter “P.005-Stop Key Mode”, and alsodepends on the actual source of drive main commands:
- P.000=0: (default configuration) main commands are coming from keypad. Therefore, the STOPkey will cause a normal stop of the motor.
- P.000>0 and P.005 = 0, pressing the STOP key will have no effect.
- P.000>0 and P.005 = 1, pressing the STOP key, the motor will execute an emergency stop,following the ramp programmed by F.206. After the speed reaches the zero value, the drive will tripwith the dedicated alarm “EMS“. An alarm reset will be needed to restore drive operation (seeparagraph 9.2).
ARTDriveG Instruction manual Chapter 6 - Drive Keypad Operation • 61
Keypad LED’s meaning:
PRG (Yellow LED): flashes if the parameters have not been permanently saved to memory.
REV (Green LED): reverse running (*)
FWD (Green LED): forward running (*)
Hz,A,V (Red LEDs): Indicates the unit of measurement of the parameter currently displayed (**).
NOTE! (*) Green LEDs blinking denote the action of the motor stall prevention.
(**) Red LEDs blinking denote an active alarm condition.
The pictures below show the alphanumeric LCD display and 7 segments display meaning (both available):
Res
et
Hz A VPrg Rev Fwd
S.000
Parameter code (Mains voltage)
Menu S (STARTUP)
Hz A VPrg Rev Fwd
STARTUP S000Mains voltage
Parameter name
Menu Parameter code
6.2 Language Selection
Available only in KB-EV-LCD/.. type keyboards.
The type keyboard has a “two languages at once” feature. The following versions are available (check the type on the labelat the rear):
- KB-EV-LCD/I English and Italian version
- KB-EV-LCD/F English and French version
- KB-EV-LCD/D English and German version
- KB-EV-LCD/E English and Spanish version
The default language for all versions is English.
To select the second language (e.g. Italian in the “KB-EV-LCD/I” keyboard version, or French, in the “KB-EV-LCD/F” keyboardversion) follow the procedure described below:
1 - Switch-on the drive
2 - Press the Prg key for about 5 sec., the display will show: Drv 03.04.00.00
Keypad V3.000
3 - Press the key, the display will show: Language:
English
4 - To select the second language, press or 5 - Press the E key to confirm.
6.3 Updating the language in E@syDrives
The keyboard language can be changed with another language of any version of the KB-EV-LCD/ keyboard.
Necessary tools A PC with a series connection to connect the drive, the E@sy Drives CD-Rom delivered with the drive, and
62 • Chapter 6 - Drive Keypad Operation ARTDriveG Instruction manual
the RS485 kit (protected cable with connectors and PCI485 for connection using the RS485series line: cod. SIEI S5QQ1
1) Install the E@syDrives program and connect the computer series port to the XS connector of the drive.
2) Power on the drive.
3) Follow the instructions of the E@syDrives program and begin a “Working Session”
4) Check to ensure that E@syDrives is connected to the drive ( check the lower righ hand corner for the display of the"CONNECTED" message.)
5) Execute the Service\Update keypad command
6) Press the "Browse" button and search until you find the file with the language you require. The file will be found in thedirectory corresponding to the firmware version of the drive. (The directory corresponding to the version of the drivefirmware is shown by default).
7) Click on the "Download" button. This operation will take some time. During this phase a progress bar indicates theprocess.
8) If the operation is completed without errors the message "Loading completed" is shown.
6.4 Moving Through the Drive Main Menu
Soon after, the keypad display will show "Output frequency (d.000)" parameter of DISPLAY menu.
DISPLAY d000
- - - - - - - - - - - - - -
Output frequency
0.0 Hz
STARTUP S000
- - - - - - - - - - - - - -
INTERFACE I000
- - - - - - - - - - - - - -
FREQ & RAMP F000
- - - - - - - - - - - - - -
PARAMETER P000
- - - - - - - - - - - - - -
APPLICATION A000
- - - - - - - - - - - - - -
COMMAND C000
- - - - - - - - - - - - - -
Prg
Prg
Prg
Prg
Prg
Prg
Prg
Menu of read-only parameters (display)
Menu of basic drive start up parameters
Menu of input/output drive settings (digital/analog)
Menu of multi frequencies and ramps settings
Menu of read/write drive parameters
Menu of PID function settings
Menu of control-type parameters (Save, Load default, etc.)
Prg
ARTDriveG Instruction manual Chapter 6 - Drive Keypad Operation • 63
6.5 Scrolling Through the Drive Parameters
INTERFACE menu example:
INTERFACE I000
- - - - - - - - - - - - - -
INTERFACE I001
- - - - - - - - - - - - - -
INTERFACE I002
- - - - - - - - - - - - - -
INTERFACE I775
- - - - - - - - - - - - - -
----------------
6.6 Parameters Modification
Example: how to change a frequency reference (FREQ & RAMP menu).
FREQ & RAMP F100
Frequency ref 0 E Frequency ref 0
0.0 Hz
Decrease
Frequency ref 0
- 200 Hz
Frequency ref 0
10.0 Hz
Increase
ETo confirmnew setting
NOTE! Same procedure is also valid to Enable/Disable a function (i.e.: S.401 Auto boost en) or program thedrive I/Os (i.e.: I.000 Dig input 1 cfg, etc. …).
64 • Chapter 6 - Drive Keypad Operation ARTDriveG Instruction manual
6.7 Quickstart procedure
Basic settings for trial run
Goto menu S – Startup, and proceed to step 2.
Set the drive input mains voltage Edit parameter S.000 to set the nominal voltage of inputmains (ex. 220V, 400V, 460V, 575V). Goto step 3.
Set the drive input mains frequency Edit parameter S.001 to set the nominal frequency of inputmains (50Hz or 60Hz). Goto step 4.
Set the maximum voltage to be applied Set parameter S.100 to the rated voltage of the motor into the motor use, as shown in the nameplate. Goto step 5.
Set the rated current of the motor Set parameter S.150 to the full load current of the motor inuse, as shown in the nameplate. Goto step 6.
Set the pole pairs of the motor Set parameter S.151 to number of pole pairs of the motorin use (number of poles divided by 2). Goto step 7.
Set the power factor of the motor Set parameter S.152 to the rated power factor of the motorin use, as shown in the nameplate.
At this point, the drive is ready for a trial run. Applying +24V between terminals 5 and 8, and pressing theSTART button on the keypad, the drive will start and the motor will accelerate up to a frequency equal to theone of the input AC mains.
NOTE! Before executing the trial run, make sure that motor rotation at rated frequency is compatiblewith the applied load. If not, skip the test run and proceed to the standard settings.
It is possible to execute the trial run at reduced speed, by setting the value of parameter S.203to the desired value of the output frequency, prior to give the START command.
Standard settings
Select the source of drive main commands. By default, the drive is started and stopped by pressing theSTART and STOP buttons on the keypad, provided +24Vare applied between terminals 5 and 8, as safety interlock.If this setting is satisfactory, skip to step 9, otherwisechange the value of S.200 as follows:S.200 = [0] Start & Stop are given by pressing therelative keypad buttons. (+24V between terminal 5 and 8must be applied as safety interlock). This is the defaultsetting.
S.200 = [1] Start & Stop are given by asserting and de-asserting drive terminal 5.
NOTE! It is possible to program several other sources forStart and Stop commands. See chap 7.6, sectionCommands, for details.
Goto step 9.
2
1
4
3
6
5
8
7
ARTDriveG Instruction manual Chapter 6 - Drive Keypad Operation • 65
Set the drive maximum allowed By default, the reference frequency is limited to the frequencyreference frequency of the input mains. If the application requires higher settings
of the motor reference frequency, increase the value ofparameter S.201. Goto step 10.
Select the source of drive main By default, the drive frequency reference is the value written
frequency reference. in parameter S.203.
If this setting is satisfactory, skip to step 11, otherwisechange the source of the drive reference frequency, bysetting S.202 as follows:
S.202 = [1] Analog input 1 is the drive frequencyreference.
S.202 = [3] The value of S.203 is the drive frequencyreference. This is the default setting.
S.202 = [5] Motorpotentiometer F.000 is the drivefrequency reference. Refer to chap. 7.5,section Motorpotentiometer, for details.
NOTE! It is possible to program several other sources forthe drive frequency reference. See chap 7.5,section Reference Sources, for details.
Goto step 12.
Set the drive acceleration and deceleration Edit parameter S.300 to set the desired acceleration time.ramp times. This is the time needed to accelerate from zero to rated
frequency, and is expressed in seconds.
Edit parameter S.301 to set the desired deceleration time.This is the time needed to decelerate from rated frequencyto zero, and is expressed in seconds.
Set the voltage boost characteristic of the drive If the drive is connected to multiple motors, or if the motorrated current is less than one fifth of the drive rated current,set the manual boost S.400 and skip to point 15. Otherwise,enable the automatic voltage boost (S.401 = [1]) and goto13. For details about the voltage boost setting, refer to chap.7.6, section Boost.
Set the slip compensation characteristic Slip compensation is needed if the natural speed variationof the drive of the motor due to the applied load is an issue for the
application. If not, skip to point 14. Amount of slipcompensation is set by the parameter S.450. S.450 =100%, means that the rated slip (evaluated from nameplatesand measured resistance) is assumed at rated motorcurrent. Dynamics of the slip estimation is set by theparameter S.451. Refer to chap. 7.6, section SlipCompensation for details.
10
9
11
12
13
66 • Chapter 6 - Drive Keypad Operation ARTDriveG Instruction manual
14
15
Measure the resistance of stator windings If the resistance of stator windings is known, its ohmicvalue can be entered in parameter S.153, and the autotuningprocedure can be skipped. Otherwise, execute theautotuning command (S.900 = [1]) and wait for theprocedure to end. Goto 15.
Save drive parameters. Execute the Save Parameter command (S.901 = [1]), inorder to store the actual set of parameters in the drivepermanent memory. If this operation is not performed, allthe modified parameters will be restored to the last savedvalue if the power is cycled.
Advanced settings
Depending on the application, it may be necessary to change drive parameters that are not included in theStartup menu. Refer to chapters 7.4 through 7.7 for a complete explanation of available drive functions.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 67
Menu d - DISPLAY
Menu S - STARTUP
Menu I - INTERFACE
Menu F - FREQ & RAMP
Menu P - PARAMETER
Menu A - APPLICATION
Menu C - COMMAND
Menu H - HIDDEN
Menu of read-only parameters (display)
Menu for basic drive start up
Menu of input/output settings (digital/analog, serial, etc.)
Menu of multi frequencies and ramps settings
Menu for drive regulation and optimization
Menu for PID function settings
Menu of control-type parameters (Save, Load default, etc.)
Menu not available on the keypad. It is reserved to set the drive parametersthrough Serial line and/or through Field bus cards.
Chapter 7 - Parameter Description
7.1 Parameters List
Legend of drive menu contents.
NOTE! In this chapter, the functions of each drive parameter are described. Depending on the keypads type,only the "parameter code" will be displayed for the KBG-1 (7 segments display), and for the KBG-LCD(alphanumeric LCD display) the "parameter code and name" will be displayed (see chapter 6).
In any case, chapter 7 describes the code and the name of each single parameter.
68 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Figure 7.1: Parameters Description Legend
CODE: Parameter Code, showed on display.Format = X.YYY:
X = Menu d=DISPLAYS=STARTUPI=INTERFACEF=FREQ & RAMPSP=PARAMETERA=APPLICATIONC=COMMANDH=HIDDEN
YYY = Parameter number
S.000
S.001
Mains voltage
Mains frequency
Rated value of the linevoltage
Rated value of the linefrequency
230380400420440460480500575
5060
230V, only for AGy-4380V, only for AGy-4400V, only for AGy-4420V, only for AGy-4440V, only for AGy-4460V, only for AGy-4480V, only for AGy-4500V, only for AGy-5575V, only for AGy-5
50Hz60Hz
(****)
(****)
(****)
(****)
(****)
(****)
V
Hz
404(P.020)
405(P.021)
PO
WE
R S
UP
PLY
START-UP
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
S.M
EN
U
(AL
IAS)
NOTE! (ALIAS): On STARTUP menu only. Parameter code of same parameter on other menu .
(*): Parameter value depends on the drive size.
(**): Parameter value depends on the drive nominal main voltage and main frequency.
(***): Value depends on the setting of another parameter.
(****): Value depends on the drive type: 400V, 460 o 575V input.
[CODE]: PICK LIST CODE [IN BRAKET]LCD SELECTION: TEXT ON DISPLAY
LCD DISPLAY: Parameter name,showed on display
Par
amet
er d
efau
lt va
lue
Par
amet
er m
inim
um v
alue
Par
amet
er m
axim
um v
alue
Par
amet
er u
nit
of m
easu
re
Par
amet
er s
tep
of v
aria
tion
Par
amet
er s
w n
umbe
r, us
ed v
ia s
eria
l
If IPA bold =
not writable parameterwith running motor.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 69
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
Bas
ic
d.000
d.001
d.002
d.003
d.004
d.005
d.006
d.007
d.008
d.050
d.051
d.052
d.053
d.054
d.100
d.101
d.102
d.120
d.121
d.122
d.150
d.151
d.152
d.170
Output frequency
Frequency ref
Output current
Output voltage
DC link voltage
Power factor
Power [kW]
Output speed
Speed ref
Heatsink temp
Drive OL
Motor OL
Brake res OL
Dig inp status
Term inp status
Vir dig inp stat
Exp dig inp stat
Exp term inp
Vir exp dig inp
Dig out status
Drv dig out sta
Vir dig out sta
Exp dig out sta
Drive output frequency
Drive frequency reference
Drive output current (rms)
Drive output voltage (rms)
DC Bus drive voltage (DC)
Power factor
Power
Drive output speed(d.000)*(P.600)
Drive speed reference(d.001)*(P.600)
Drive heatsink temperature(linear sensor measured)
Drive overload (100% =alarm threshold)
Motor overload (100% =alarm threshold)
Braking resistor overload(100%=alarm thr)
Reserved
Digital inputs statusacquired by the drive(terminal or virtual)
Digital inputs terminal statusof the drive regulat. board
Virtual digital inputs statusfrom drive serial link orfield bus card
Expansion digital inputsstatus (optional terminal orvirtual)
Expansion digital inputsterminal status of the driveexpansion board
Expansion virtual digitalinputs status from driveserial link or field bus card
Digital outputs status on theterminals of the driveregulation board (com-manded by DO functions orvirtual DO)
Digital outputs status,commanded by DO functions
Virtual digital outputsstatus, commanded viaserial link or field bus cardExpansion digital outputsstatus on the terminals ofthe drive regulation board(commanded by DOfunctions or virtual DO)
Hz
Hz
A
V
V
kW
°C
%
%
%
°C
0.01
0.01
0.1
1
1
0.01
0.01
0.01/1
0.01/1
1
0.1
0.1
0.1
1
001
002
003
004
005
006
007
008
009
010
011
012
013
058
014
015
016
017
018
019
020
021
022
023
DISPLAY
Ove
rlo
adIn
pu
t/O
utp
ut
70 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
Inp
ut/
Ou
tpu
t
Exp DrvDigOutSta
Exp vir dig sta out
An in 1 cnf mon
An in 1 monitor
An in 1 term mon
An in 2 cnf mon
An in 2 monitor
An in 2 term mon
An in 3 cnf mon
An in 3 monitor
An in 3 term mon
EncPulses/Sample
Encoder freq
Encoder speed
Option 1 state
d.171
d.172
d.200
d.201
d.202
d.210
d.211
d.212
d.220
d.221
d.222
d.300
d.301
d.302
d.350
Expansion digital outputsstatus, commanded by DOfunctions
Expansion virtual digitaloutputs status, commandedvia serial link or field buscard
Analog input 1 destination;it shows the functionassociated to this analoginput
Analog input 1 output block% value
Analog input 1 input block% value
Analog input 2 destination;it shows the functionassociated to this AI
Analog input 2 output block% value
Analog input 2 input block% value
Analog input 3 destination;it shows the functionassociated to this AI
Analog input 3 output block% value
Analog input 3 input block% value
Number of encoder pulses,recorded in the time intervaldefined by parameter I.504.
Encoder frequencyreading (Motor frequency)
Encoder speed reading(d.000)*(P.600)
Drive option 1 state(expansion board typeprogrammed)
[0] Null funct[1] Freq ref 1[2] Freq ref 2[3] Bst lev fact[4] OT lev fact[5] Vred lev fac[6] DCB lev fact[7] RampExt fact[8] Freq Ref fact[9] SpdPI LimFac[10] Mlt rif frq 1[11] Mlt rif frq 2
As for d.200
As for d.200
01234..32
33
34
..646566
ReservedReservedReservedReservedData exchange..Regulation board error(board type)Regulation board error(checksum)Regulation board error(board incompatible)..Expansion errorReservedReserved
Hz
0.001
0.01
0.01/1
024
025
026
027
028
029
030
031
032
033
034
035
036
037
038
En
cod
erO
PTI
ON
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 71
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
d.351
d.353
d.354
d.400
d.401
d.402
d.403
d.404
d.800
d.801
d.802
d.803
d.950
d.951
d.952
d.953
d.954
d.955
d.956
d.957
Option 2 state
SBI State
SBI Baudrate
PID reference
PID feedback
PID error
PID integr comp
PID output
1st alarm-latest
2nd alarm
3rd alarm
4th alarm
Drive rated curr
SW version (1/2)
SW version (2/2)
Power ident code
Param ident code
Regul ident code
Startup id code
Drive size
Drive option 2 state(expansion board typeprogrammed)
Communication statebetween SBI and Master
Communication speedbetween SBI and Master
PID reference signal
PID feedback signal
PID error signal
PID integral component
PID output signal
Last alarm stored by thedrive alarm list
Second to last alarm
Third to last alarm
Fourth to last alarm
Drive rated current (itdepends on the drive size)
Software version - part 1
Software version - part 2
Reseved
Reseved
Reseved
Reseved
Drive size code
As for d.350
0123
01234567815
See paragraph9.3
03.01
00.00
01234567891011
Wait parametrizationWait configurationData exchangeError
12 Mbit / s6 Mbit / s3 Mbit / s1.5 Mbit / s500 Kbit / s187.5 Kbit / s93.75 Kbit / s45.45 Kbit / s19.2 Kbit / sunknown
0.75kW - 230/400/460V1.5kW - 230/400/460V2.2kW - 230/400/460V3kW - 230/400/460V4kW - 230/400/460V5.5kW - 230/400/460V7.5kW - 230/400/460V11kW - 230/400/460V15kW - 230/400/460V22kW - 230/400/460V30kW - 230/400/460V37kW - 230/400/460V
%
%
%
%
%
0.1
0.1
0.1
0.1
0.1
0.1
0.01
0.01
039
059
060
041
042
043
044
045
046
047
048
049
050
051
052
053
054
055
056
057
PID
Ala
rm L
ist
Dri
ve I
den
tifi
cati
on
OP
TIO
N
72 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
d.958
d.999
Drive cfg type
Display Test
Drive cofiguration type
Drive display test
121314151617182125130131132133134135136137138139140141142143144145146
[0] 400Vac[1] 460 or 575Vac
061
099
Uti
lity
45kW - 230/400/460V55kW - 230/400/460V75kW - 230/400/460V90kW - 230/400/460110kW - 230/400/460V132kW - 230/400/460V160kW - 230/400/460V18.5kW - 230/400/460V200kW - 230/400/460V2.0Hp - 575V3.0Hp - 575V5.0Hp - 575V7.5Hp - 575V10Hp - 575V15Hp - 575V20Hp - 575V25Hp - 575V30Hp - 575V40Hp - 575V50 Hp - 575V60Hp - 575V75Hp - 575V100Hp - 575V125Hp - 575V150Hp - 575V200Hp - 575V
Standard: 400Vac, 50HzAmerican: 460 or 575Vac,60Hz
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 73
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
S.000
S.001
S.100
S.101
S.150
S.151
S.152
S.153
S.200
S.201
S.202
S.203
S.300
S.301
Mains voltage
Mains frequency
Max out voltage
Base frequency
Motor rated curr
Motor pole pairs
Motor power fact
Motor stator R
Cmd source sel
Max ref freq
Ref 1 channel
Frequency ref 0
Acc time 1
Dec time 1
Rated value of the linevoltage
Rated value of the linefrequency
Maximum value of thevoltage applied to the motor
Rated frequency of themotor
Rated current of the motor
Pole Pairs of the motor
Motor power factor
Measurement of the statorresistance of the motor
Source of the START andSTOP commands
Maximum frequencyreference thresholdand / or digital reference(both directions)
Source of the Reference 1
Digital speed reference(F.100)
Acceleration ramp delaytime 1
Deceleration ramp delaytime 1
230380400420440460480500575
5060
[0] Keypad
[1] Terminals
[2] Virtual
[3] Serial
[4] Control word
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Freq ref x
[4] Multispeed[5] Motorpotent
[6] Analog inp 3[7] Encoder[8] Profidrive
230V, only for AGy-4380V, only for AGy-4400V, only for AGy-4420V, only for AGy-4440V, only for AGy-4460V, only for AGy-4480V, only for AGy-4500V, only for AGy-5575V, only for AGy-5
50Hz60Hz
START & STOP viakeypad (+24V between 5& 8 terminals required).START & STOP viaterminalMain commands viaVirtual & Terminal settingMain commands via seriallineMain commands fromProfiDrive control word
NullAnalog input 1Analog input 2Frequency referenceS.203 (F.100)Multi frequenciesMotorpotientometerreferenceAnalog input 3Encoder signalReference by Profibus
(****)
(****)
(**)
(**)
(*)
(*)
(*)
(*)
0
(****)
3
(****)
5
5
(****)
(****)
50
25
(*)
1
0.01
0
0
25
0
-S.201
1(***)
1(***)
(****)
(****)
(**)
500
(*)
60
1
99.99
4
500
8
S.201
999.9(***)
999.9(***)
V
Hz
V
Hz
A
ohm
Hz
sec
sec
1
0.1
0.1
0.01
0.01
0.1
0.1(***)
0.1(***)
404(P.020)
405(P.021)
413(P.061)
414(P.062)
406(P.040)
407(P.041)
408(P.042)
409(P.043)
400(P.000)
305(F.020)
307(F.050)
311(F.100)
329(F.201)
330(F.202)
Po
wer
Su
pp
lyV
/fM
oto
r D
ata
Co
mm
an
ds
& R
efe
ren
cie
s
(AL
IAS)
START-UP
74 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
S.400
S.401
S.450
S.451
S.900
S.901
Manual boost [%]
Auto boost en
Slip compensat
Slip comp filter
Measure stator R
Save parameters
Manual boost at lowrevolutions
Automatic boost functionenabling
Slip compensation
Response time of slipcompensation
Motor tuning command
Save parameters
[0] Disable
[1] Enable
(1)
(2)
(1)
(2)
Automatic boost functiondisabledAutomatic boost functionenabled
No action
Autotune commandexecution
No action
Save parameterscommand execution
1.0
0
0
0.1
(1)
(1)
0.0
0
0
0
(1)
(1)
25.0
1
250
10
(2)
(2)
% ofS.100
% ofS.100
sec
0.1
1
0.1
421(P.120)
423(P.122)
419(P.100)
420(P.101)
806(C.100)
800(C.000)
Fu
nct
ion
sU
tilit
y
(AL
IAS)
(1) : AGy-4A, AGy-5 = Confirm? NOAGy-4 = off
(2) : AGy-4A, AGy-5 = Confirm? YESAGy-4 = do
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 75
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
I.000
I.001
I.002
I.003
I.004
I.005
Dig input 1 cfg
Dig input 2 cfg
Dig input 3 cfg
Dig input 4 cfg
Dig input 5 cfg
Dig input 6 cfg
Digital Input 1 configuration
Digital Input 2 configuration
Digital Input 3 configuration
Digital Input 4 configuration
Digital Input 5 configuration
Digital Input 6 configuration
[0] None[1] Run
[2] Reverse
[3] Ext Fault NO
[4] Ext Fault NC
[5] Alarm reset[6] Jog
[7] Freq sel 1
[8] Freq sel 2
[9] Freq sel 3
[10] Freq sel 4
[11] Ramp sel 1
[12] Ramp sel 2
[13] Enable NO
[14] Enable NC
[15] DCBrake en
[16] DCBrake
[17] Autocapture
[18] Ramp enable
[19] Zero ref
[20] PID enable
[21] PID freeze
[22] PID gain sel
[23] Motorpot Up
[24] Motorpot Dn
[25] Reset Motorp
[26] Fast stop[27] Zero freq
[28]Stop(3wires)
[29]Local/Remote
[30] En lim Steady
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
Not activeRUN command for themotor STARTSpeed REVERSEcommandExternal fault with NO(Normal Open) contactExternal fault with NC(Norm. Closed) contactAlarm reset commandJOG frequency refer-ence enablingBinary selection forMultispeedBinary selection forMultispeedBinary selection forMultispeedBinary selection forMultispeedBinary selection forMultirampBinary selection forMultirampDrive Enable with NC(Norm. Closed) contactDrive Enable with NO(Normal Open) contactEnabling of the DCbraking functionCommand for executionof DC brakingExecution of the flyingrestartEnabling / Disabling of theRamp blockRamp to 0Hz & maincommands activeEnabling of the PIDregulation.Enabling PID freezeoutput signal.Selection of the PIDregulator gain.Motorpotentiometerreference increasingMotorpotentiometerreference decreasingReset ofMotorpotentiometer ref.Emergency stopOutput frequency forcedto zero, following theramp programmed forFast stop (F.206).Stop function (NC) withP.001 = [2] 3 Wires.Start/Stop commands fromkeypad (Local) or fromthe source programmedby P.000 (Remote)Activate the stationarystatus current regulator.
7
8
28
6
5
3
0
0
0
0
0
0
30
30
30
30
30
30
100
101
102
103
104
105
Dig
ital
In
pu
t o
f th
e R
egu
lati
on
Bo
ard
INTERFACE
76 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
I.006
I.007
I.050
I.051
I.052
I.053
I.070
I.071
I.072
I.073
I.074
I.075
I.076
I.077
I.078
I.079
I.100
Dig input 7 cfg
Dig input 8 cfg
Exp dig in 1 cfg
Exp dig in 2 cfg
Exp dig in 3 cfg
Exp dig in 4 cfg
AND 1 out cfg
AND 2 out cfg
AND 3 out cfg
OR 1 out cfg
OR 2 out cfg
OR 3 out cfg
NOT 1 out cfg
NOT 2 out cfg
NOT 3 out cfg
NOT 4 out cfg
Dig output 1 cfg
Digital Input 7 configuration
Digital Input 8 configuration
Expansion Digital Input 1configuration (on Expan-sion board)
Expansion Digital Input 2configuration (on Expan-sion board)
Expansion Digital Input 3configuration (on Expan-sion board)
Expansion Digital Input 4configuration (on Expan-sion board)
Output block set up AND 1
Output block set up AND 2
Output block set up AND 3
Output block set up OR1
Output block set up OR 2
Output block set up OR 3
Output block set up NOT 1
Output block set up NOT 2
Output block set up NOT 3
Output block set up NOT 4
Digital Output 1 configura-tion
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
As for I.000
[0] Drive Ready[1] Alarm state
[2] Not in alarm
[3] Motor run
[4] Motor stop
[5] REV rotation
[6] Steady state
[7] Ramping
[8] UV running
[9] Out trq>thr
[10] Current lim
Drive ready to startAlarm signalling (Positivelogic)Alarm signalling (Negativelogic)Run command active oroutput frequency ≠ 0HzRun command not activeand output frequency =0HzCounter-clockwiserotation of the motor.Motor is running in steadystate.Acceleration or Decel-eration Ramp inprogress.The drive has tripped forUV, and automaticrestart is taking place.Output torque higher thanthe value of P.241.Current limit (during rampor at steady state).
1
2
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
30
30
30
30
30
30
30
30
30
30
30
30
30
30
30
30
77
106
107
108
109
110
111
186
187
188
189
190
191
192
193
194
195
112
Dig
ital
In
pu
t o
f th
e E
xpan
sio
n B
oar
dP
rog
ram
mab
le l
og
icD
igit
al O
utp
ut
of
the
Reg
ula
tio
n B
oar
d
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 77
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
[11] DC-link lim[12] Limit active
[13] Autocapt run[14] BU overload
[15] Neg pwrfact
[16] PID err ><
[17] PID err>thr[18] PID err<thr[19] PIDer><(inh)
[20] PIDerr>(inh)
[21] PIDerr<(inh)
[22] FWD enc rot
[23] REV enc rot
[24] Encoder stop[25] Encoder run
[26] Extern fault
[27] No ext fault
[28] Serial TO
[29] freq=thr1
[30] freq!=thr1
[31] freq>thr1
[32] freq<thr1
[33] freq=thr2
[34] freq!=thr2
[35] freq>thr2
[36] freq<thr2
[37] HS temp=thr
[38] HS temp!=thr
[39] HS temp>thr
[40] HS temp<thr
[41] Output freq
[42] Out freq x 2
DC Bus limit.General signalling of drivelimit condition.Autocapture in progress.Set when the integratord.054 = 100%, and Resetwhen d.054 = 0%Negative inverter outputpower factor.PID error is within the limitsdefined by A.058 and A.059.PID error is >A.058.PID error is <=A.059.PID error is within the limitsdefined by A.058 and A.059.(see chapter 7.7).PID error is >A.058 (seechapter 7.7).PID error is <=A.059 (seechapter 7.7).Clockwise rotation of theencoder.Counter-clockwiserotation of the encoder.Encoder not rotating.Encoder is rotating.general signalling.Positive logic for Ext. faultalarm signalling.Negative logic for Extern.fault alarm signalling.Serial link communicationtime out.Output frequency withinthe range defined byP.440 and P.441.Output frequency outsidethe range defined byP.440 and P.441.Output frequency abovethe values defined byP.440 and P.441.Output frequency belowthe values defined byP.440 and P.441.Output frequency withinthe range defined byP.442 and P.443.Output frequency outsidethe range defined byP.442 and P.443.Output frequency abovethe values defined byP.442 and P.443.Output frequency belowthe values defined byP.442 and P.443.Heatsink temp within therange defined by P.480and P.481.Heatsink temp outside therange defined by P.480and P.481.Heatsink temp above thethreshold defined byP.480 and P.481.Heatsink temp below thethreshold defined byP.480 and P.481.Square wave synchro-nized with the inverteroutput frequencySquare wave synchro-nized with twice theinverter output frequency
78 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
I.101
I.102
I.103
I.150
I.151
I.152
Dig output 2 cfg
Dig output 3 cfg
Dig output 4 cfg
Exp DigOut 1 cfg
Exp DigOut 2 cfg
Exp DigOut 3 cfg
Digital Output 2 configuration
Digital Output 3 configuration
Digital Output 4 configuration
Expansion Digital Output 1configuration (on Expan-sion board)
Expansion Digital Output 2configuration (on Expan-sion board)
Expansion Digital Output 3configuration (on Expan-sion board)
[43] CoastThrough
[44]EmgStop
[45] DC braking[46] Drv OL status
[47] Drv OL warn
[48] Mot OL state
[49] False[50] True[51] Reserved[52] Reserved[53] Reserved[54] Reserved[55] Reserved[56] DI 1[57] DI 2[58] DI 3[59] DI 4[60] DI 5[61] DI 6[62] DI 7[63] DI 8[64] Exp DI 1
[65] Exp DI 2
[66] Exp DI 3
[67] Exp DI 4
[68] AND 1 out[69] AND 2 out[70] AND 3 out[71] OR 1 out[72] OR 2 out[73] OR 3 out[74] NOT 1 out[75] NOT 2 out[76] NOT 3 out[77] NOT 4 out
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
Kinetic energy recoveringduring mains lossEmergency stop aftermains loss detectionCD braking in progressSet when the integratord.051 = 100%, and Resetwhen d.051 = 0%Set if d.051 is greater orequal to 90%Set when the integratord.052 = 100%, and Resetwhen d.052 = 0%False assume value 0True assume value 1
State of digital input 1State of digital input 2State of digital input 3State of digital input 4State of digital input 5State of digital input 6State of digital input 7State of digital input 8Digital input 1 expansionstateDigital input 2 expansionstateDigital input 3 expansionstateDigital input 4 expansionstateOutput block AND 1 stateOutput block AND 2 stateOutput block AND 3 stateOutput block OR 1 stateOutput block OR 2 stateOutput block OR 3 stateOutput block NOT 1 stateOutput block NOT 2 stateOutput block NOT 3 stateOutput block NOT 4 state
6
3
1
0
0
0
0
0
0
0
0
0
113
114
115
116
117
180
77
77
77
77
77
77
Dig
. Out
puto
f the
Exp
. Boa
rd
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 79
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
I.200
I.201
I.202
I.203
I.204
I.205
I.210
I.211
I.212
I.213
I.214
I.215
I.220
I.221
I.222
I.223
I.224
I.225
I.300
An in 1 Type
An in 1 offset
An in 1 gain
An in 1 minimum
An in 1 filter
An In 1DeadBand
An in 2 Type
An in 2 offset
An in 2 gain
An in 2 minimum
An in 2 filter
An In 2DeadBand
An in 3 Type
An in 3 offset
An in 3 gain
An in 3 minimum
An in 3 filter
An In 3DeadBand
Analog out 1 cfg
Setting of the Analog Input1 type reference (voltage)
Analog Input 1 offset
Analog Input 1 gain
An Input 1 minimun value
Time constant of digitalfilter on Analog input 1
Analog Input 1dead band
Setting of the Analog Input2 type reference (voltage)
Analog Input 2 offset
Analog Input 2 gain
An Input 2 minimun value
Time constant of digitalfilter on Analog input 2
Analog Input 2dead band
Setting of the Analog Input3 type reference (current)
Analog Input 3 offset
Analog Input 3 gain
An Input 3 minimun value
Time constant of digitalfilter on Analog input 3
Analog Input 3dead band
Analog Output 1 configura-tion
[0] ± 10V[1] 0-10V/0-20mA
[0] ± 10V[1] 0-10V/0-20mA
[1] 0-10V/0-20mA[2] 4-20mA
[0] Freq out abs
[1] Freq out[2] Output curr[3] Out voltage[4] Out trq (pos)
[5] Out trq (abs)
[6] Out trq[7] Out pwr (pos)
[8] Out pwr (abs)
[9] Out pwr[10] Out PF[11] Enc freq abs
[12] Encoder freq[13] Freq ref abs
[14] Freq ref[15] Load current[16] Magn current
[17] PID output[18] DClink volt
Bipolar ± 10VUnipolar +10V
Bipolar ±10VUnipolar +10V
0…20mA4…20mA
Output Frequencyabsolute value.Output Frequency.Output Current.Output Voltage.Output Torque positivevalue.Output Torque absolutevalue.Output Torque.Output Power positivevalue.Output Power absolutevalue.Output Power.Output Power Factor.Encoder frequencyabsolute value.Encoder frequency.Frequency referenceabsolute value.Frequency referenceLoad Current.Motor MagnetizingCurrent.PID regulator output.DC bus capacitors level.
1
0
1
0
0.1
0
0
0
1
0
0.1
0
1
0
1
0
0.1
0
0
0
-99.9
-9.99
0
0.001
0
0
-99.9
-9.99
0
0.001
0
1
-99.9
-9.99
0
0.001
0
0
1
99.9
9.99
99.99
0.25
99.9
1
99.9
9.99
99.99
0.25
99.9
2
99.9
9.99
99.99
0.25
99.9
22
%
%
%
sec
%
%
%
%
sec
%
%
%
%
sec
%
0.1
0.01
0.01
0.001
0.1
0.1
0.01
0.01
0.001
0.1
0.1
0.01
0.01
0.001
0.1
118
119
120
121
122
182
123
124
125
126
127
183
128
129
130
131
132
184
133
An
alo
g I
np
ut
Reg
ula
tio
n B
oar
dA
nal
og
Ou
tpu
t R
egu
lati
on
Bo
ard
80 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
I.301
I.302
I.303
I.310
I.311
I.312
I.313
I.350
I.351
I.352
I.353
I.400
I.410
I.420
I.430
I.440
I.450
I.500
I.501
I.502
I.503
I.504
I.505
An out 1 offset
An out 1 gain
An out 1 filter
Analog out 2 cfg
An out 2 offset
An out 2 gain
An out 2 filter
Exp an out 1 cfg
Exp AnOut 1 offs
Exp AnOut 1 gain
Exp AnOut 1 filt
Inp by serial en
Exp in by ser en
Out by serial en
Exp OutBySer en
An Inp by ser en
An out by ser en
Encoder enable
Encoder ppr
Enc channels cfg
Enc spd mul fact
Enc update time
Enc supply
Analog output 1 offset
Analog output 1 gain
Time constant of outputfilter
Analog Output 2 configura-tion
Analog output 2 offset
Analog output 2 gain
Time constant of outputfilter
Expansion Analog Output 1configuration (on Exp.board)
Expansion Analog Output 1offset
Expansion Analog Output 1gain
Time constant of outputfilter
Virtual Digital enabling
Expansion Virtual DigitalInputs enabling
Virtual Digital Outputssetting enabling
Expansion Virtual DigitalOutputs enabling
Virtual Analog Inputsenabling
Virtual Analog Outputsenabling
Enabling of the encodermeasure
Encoder nameplate pulsesper revolution
Encoder channelsconfiguration
Multiplier factor of theencoder pulses, set in theI.501
Encoder pulses samplingtime
Encoder power supplylevel
[19] U current
[20] V current
[21] W current
[22] Freq ref fac
As for I.300
As for I.300
[0] Disable[1] Enable
[0] One Channel[1] Two Channels
[0] 1ms[1] 4ms[2] 16ms[3] 0.25s[4] 1s[5] 5s
[0] 5.2V[1] 5.6V[2] 8.3V[3] 8.7V
Output phase U currentsignal.Output phase V currentsignal.Output phase W currentsignal.Multiplier factor forfrequency reference
Encoder measure disabled.Encoder measure enabled.
A (K1) encoder channelA and B (K1 and K2)encoder channels
0
1
0
2
0
1
0
3
0
1
0
0
0
0
0
0
0
0
1024
1
1
0
0
9.99
9.99
2.5
22
9.99
9.99
2.5
22
9.99
9.99
2.5
255
15
15
3
255
255
1
9999
1
99.99
5
3
sec
sec
sec
-9.99
-9.99
0
0
-9.99
-9.99
0
0
-9.99
-9.99
0
0
0
0
0
0
0
0
0
0
0.01
0
0
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
196
149
150
151
152
153
154
181
An
alo
g O
utp
ut
Exp
Bo
ard
En
ablin
g V
irtu
al I
/OE
nco
der
Co
nfi
g
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 81
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
I.600
I.601
I.602
I.603
I.604
I.605
I.700
I.701
I.750
I.751
I.752
I.753
I.754
I.760
I.761
Serial link cfg
Serial link bps
Device address
Ser answer delay
Serial timeout
En timeout alm
Option 1 type
Option 2 type
SBI address
CAN baudraute
SBI Profibus mod
SBI CAN mode
Bus Flt Holdoff
SBI to Drv W 0
SBI to Drv W 1
Serial line configurationprotocol & mode
Serial line baudrate
Serial line address of thedrive
Serial line answer delaytime
Serial line transmissiontimeout
Setting time out alarm
Expansion optional 1 cardtype(Note: Selected boardmust be installed on drive)
Expansion optional 2 cardtype(Note: Selected boardmust be installed on drive)
SBI Address
CAN Open baudraute
SBI Profibus Mode
Selection of the Busprotocol
Delay time for Bus FaultAlarm from profibus
Word 0 from SBI to drive
Word 1 from SBI to drive
[0] FoxLink 7E1[1] FoxLink 701[2] FoxLink 7N2[3] FoxLink 8N1[4] ModBus 8N1[5] JBus 8N1
[0] 600 baud[1] 1200 baud[2] 2400 baud[3] 4800 baud[4] 9600 baud[5] 19200 baud[6] 38400 baud
[0] Disable
[1] Enable
[0] Board Off[1] Board master[2] IO Board[3] Board free[4] SBI Board
[0] Board Off[1] Board master[2] IO Board[3] Board free[4] SBI Board
[0] 10 Kbit/s[1] 20 Kbit/s[2] 50 Kbit/s[3] 125 Kbit/s[4] 250 Kbit/s[5] 500 Kbit/s[6] 1000 Kbit/s
[0] Custom[1] PPO1[2] PPO2[3] PPO3[4] PPO4
[0] OFF[1] CAN Open[2] DeviceNet
FoxLink 7E1 7 Even 1FoxLink 7O1 7 Odd 1FoxLink 7N2 7 None 2FoxLink 7O1 8 None 1Modbus 8N1 8 None 1Jbus 8N1 8 None 1
600 baud rate1200 baud rate2400 baud rate4800 baud rate9600 baud rate19200 baud rate38400 baud rate
Drive NOT in alarm andsignal on a digital outputDrive IN alarm and signalon a digital output
NoneReservedEXP-D6-A1R1-AGyResevedSBI-PDP-AGy
NoneReservedEXP-D6-A1R1-AGyReservedSBI-PDP-AGy
Profidrive customProfidrive type 1Profidrive type 2Profidrive type 3Profidrive type 4
NoneCAN Open protocolDeviceNet protocol
4
4
1
1
0
0
0
0
3
5
2
0
0.0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0
0
0
5
6
99
250
25
1
4
4
255
6
4
2
60.0
1999
1999
155
156
157
158
159
160
161
162
163
164
165
166
179
167
168
PR
OTO
CO
L
TY
PE
DA
TA B
IT
PA
RIT
Y
ST
OP B
IT
Ser
ial
Lin
e C
on
fig
Op
tio
n C
on
fig
Bo
ard
Fie
ld B
us
Co
nfi
g
82 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
I.762
I.763
I.764
I.765
I.770
I.771
I.772
I.773
I.774
I.775
SBI to Drv W 2
SBI to Drv W 3
SBI to Drv W 4
SBI to Drv W 5
Drv to SBI W 0
Drv to SBI W 1
Drv to SBI W 2
Drv to SBI W 3
Drv to SBI W 4
Drv to SBI W 5
Word 2 from SBI to drive
Word 3 from SBI to drive
Word 4 from SBI to drive
Word 5 from SBI to drive
Word 0 from drive to SBI
Word 1 from drive to SBI
Word 2 from drive to SBI
Word 3 from drive to SBI
Word 4 from drive to SBI
Word 5 from drive to SBI
0
0
0
0
1
2
3
4
5
6
0
0
0
0
0
0
0
0
0
0
1999
1999
1999
1999
1999
1999
1999
1999
1999
1999
169
170
171
172
173
174
175
176
177
178
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 83
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
FREQ & RAMPF.000
F.010
F.011
F.012
F.013
F.013
F.020
F.021
F.050
F.051
F.060
F.061
F.080
F.100
F.101
F.102
Motorpot ref
Mp acc/dec time
Motorpot offset
Mp output mode
Mp auto save
MpRef at stop
Max ref freq
Min ref freq
Ref 1 channel
Ref 2 channel
MltFrq channel 1
MltFrq channel 2
FreqRef fac src
Frequency ref 0
Frequency ref 1
Frequency ref 2
Motopot reference (it canbe set using up and downcommands)
Motorpot Accel. and Decel.ramp time
Motopotentiometer minimumreference
Unipolar / bipolarMotorpotentiometer
Motopotenziometer autosave function
Behavior of the frequencyreference fromMotorpotentiometer duringa Stop sequence
Motor maximum frequencyvalue (for both directions)
Minimum frequency value
Source of the Reference 1
Source of the Reference 2
Source of the Multispeed 1
Source of the Multispeed 2
Frequency referencemultiplier factor source
Digital Reference frequency 0
Digital Reference frequency 1
Digital Reference frequency 2
[0] Unipolar
[1] Bipolar
[0] Disable
[1] Enable
[0] Last value
[1] Follow ramp
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Freq ref x
[4] Multispeed[5] Motorpotent
[6] Analog inp 3[7] Encoder[8] Profidrive
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Freq ref x
[4] Multispeed[5] Motorpotent
[6] Analog inp 3[7] Encoder[8] Profidrive
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3
MotorpotentiometerunipolarMotorpotentiometerbipolar
Motorpot auto savefunction disabledMotorpot auto savefunction enabled
Mot. reference will retainits current valueMot. reference will rampdown to zero, following thedeceleration ramp in use
NullAnalog input 1Analog input 2Frequency referenceF.100 (S.203)Multi frequnciesMotorpotientometerreferenceAnalog input 3Encoder signalReference by Profibus
NullAnalog input 1Analog input 2Frequency referenceF.101MultispeedMotorpotientometerreferenceAnalog input 3Encoder signalReference by Profibus
As for F.050, Reference1 source
As for F.051, Reference2 source
NullAnalog input 1Analog input 2Analog input 2
0
10
0
0
1
0
(****)
0
3
0
3
3
0
(****)
0
0
0
0.1
0
0
0
0
25
0
0
0
0
0
0
-F.020
-F.020
-F.020
F.020
999.9
F.020
1
1
1
500
F.020
8
8
8
8
3
F.020
F.020
F.020
Hz
sec
Hz
Hz
Hz
Hz
Hz
Hz
300
301
302
303
304
351
305
306
307
308
309
310
342
311
312
313
Mo
torp
ote
nti
om
ete
rR
efe
ren
ce
Lim
it
0.01
0.1
0.1
0.1
0.1
0.1
0.1
0.1
Re
fere
nc
e S
ou
rce
sM
ult
i F
req
uen
cy F
un
ctio
n
84 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
F.103
F.104
F.105
F.106
F.107
F.108
F.109
F.110
F.111
F.112
F.113
F.114
F.115
F.116
F.200
F.201
F.202
F.203
F.204
F.205
F.206
F.207
F.208
F.250
F.260
F.270
F.271
F.272
Frequency ref 3
Frequency ref 4
Frequency ref 5
Frequency ref 6
Frequency ref 7
Frequency ref 8
Frequency ref 9
Frequency ref 10
Frequency ref 11
Frequency ref 12
Frequency ref 13
Frequency ref 14
Frequency ref 15
Jog frequency
Ramp resolution
Acc time 1
Dec time 1
Acc time 2
Dec time 2
Acc time 3
Dec time 3 / FS
Acc time 4 / Jog
Dec time 4 / Jog
Ramp S-shape
Ramp extens src
Jump amplitude
Jump frequency 1
Jump frequency 2
Digital Reference frequency 3
Digital Reference frequency 4
Digital Reference frequency 5
Digital Reference frequency 6
Digital Reference frequency 7
Digital Reference frequency 8
Digital Reference frequency 9
Digital Refer. frequency 10
Digital Refer. frequency 11
Digital Refer. frequency 12
Digital Refer. frequency 13
Digital Refer. frequency 14
Digital Refer. frequency 15
Jogging frequencyreference
Accuracy of the rampsetting
Acceleration ramp timedelay 1
Deceleration ramp timedelay 1
Acceleration ramp timedelay 2
Deceleration ramp timedelay 2
Acceleration ramp timedelay 3
Deceleration ramp timedelay 3 / Fast Stop decel.
Accel. ramp time delay 4 /Accel. time in jogging state
Decel. ramp time delay 4 /Decel. time in jogging state
S Ramp shaping
Source for the Ramp timeextension function
Jump frequencieshysteresis
Jump frequency 1
Jump frequency 2
[0] 0.01s[1] 0.1s[2] 1s
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3
From 0.01s to 99.99sFrom 0.1s to 999.9sFrom 1s to 9999s
NullAnalog input 1Analog input 2Analog input 3
0
0
0
0
0
0
0
0
0
0
0
0
1
1
5
5
5
5
5
5
5
5
0
0
0
0
0
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
-F.020
0
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0
0
0
0
0
F.020
F.020
F.020
F.020
F.020
F.020
F.020
F.020
F.020
F.020
F.020
F.020
F.020
F.020
2
999.9(***)
999.9(***)
999.9(***)
999.9(***)
999.9(***)
999.9(***)
999.9(***)
999.9(***)
10
3
100
500
500
Hz
Hz
Hz
Hz
Hz
Hz
Hz
Hz
Hz
Hz
Hz
Hz
Hz
Hz
sec
sec
sec
sec
sec
sec
sec
sec
sec
Hz
Hz
Hz
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1(***)
0.1
0.1
0.1
0.1
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341Jum
p f
req
uen
cyR
amp
Co
nfi
g
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 85
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
PARAMETERP.000
P.001
P.002
P.003
P.004
P.005
P.010
P.020
P.021
P.040
P.041
P.042
P.043
P.044
P.045
Cmd source sel
RUN /REV cmd mode
Reversal enable
Safety
Stop mode
Stop Key Mode
Control Mode
Mains voltage
Mains frequency
Motor rated curr
Motor pole pairs
Motor power fact
Motor stator R
Motor cooling
Motor thermal K
It defines the use of STARTand STOP commands
Command logic
Reversal enabling
Safe start definition
Motor stop control function
STOP key configuration
Drive control mode
Rated value of the linevoltage
Rated value of the linevoltage frequency
Rated current of the motor
Pole Pairs of the motor
Motor power factor
Measurement of the statorresistance of the motor
Motor type cooling
Motor thermal constant
[0] Keypad
[1] Terminals
[2] Virtual
[3] Serial
[4] Control word
[0] Run / Rev
[1] Fwd / Rev
[2] 3-Wires
[0] Disable
[1] Enable
[0] OFF
[1] ON
[0] Ramp to stop[1] Coast to stop
[0] Not active[1] EmgStop&Al
[0] V/f open loop
[1] V/f clsd loop
230380400420440460480500575
5060
[0] Natural[1] Forced
START & STOP viakeypad (+24V between 5& 8 terminals required).START & STOP viaterminalMain commands viaVirtual & Terminal settingMain commands viaserial lineMain commands fromProfiDrive control word
Run and ReversecommandsRun Forward and RunReverse commandsRun , Stop and Reversecommands
Disabling reverserotationEnabling reverse rotation
START allowed with RUNtemirnal connected at thepower onSTART not allowed withRUN temirnal connectedat the power on
Ramp to stopCoast to stop
No actionEmergency stopexecution and trippingwhen zero speed isreached
V/f control w/o encoderfeedbackV/f control with encoderfeedback
230V, only for AGy-4380V, only for AGy-4400V, only for AGy-4420V, only for AGy-4440V, only for AGy-4460V, only for AGy-4480V, only for AGy-4500V, only for AGy-5575V, only for AGy-5
50Hz60Hz
Self ventilatedAssisted ventilation
0
0
1
1
0
1
0
(****)
(****)
(*)
(*)
(*)
(*)
0
30
0
0
0
0
0
0
0
(****)
(****)
(*)
1
0.01
0
0
1
4
2
1
1
1
1
1
(****)
(****)
(*)
60
1
99.99
1
120
V
Hz
A
ohm
min
0.1
0.01
0.01
400
401
402
403
493
496
498
404
405
406
407
408
409
410
411
Co
mm
an
ds
Po
wer
Su
pp
lyM
oto
r D
ata
Cont
rol M
ode
86 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
P.060
P.061
P.062
P.063
P.064
P.080
P.081
P.100
P.101
P.120
P.121
P.122
P.140
P.160
P.170
P.171
P.172
P.173
P.174
P.175
P.176
P.177
P.178
V/f shape
Max out voltage
Base frequency
V/f interm volt
V/f interm freq
Max output freq
Min output freq
Slip compensat
Slip comp filter
Manual boost [%]
Boost factor src
Auto boost en
Magn curr gain
Osc damping gain
SpdPgainL
SpdIgainL
SpdPgainH
SpdIgainH
SpdGainThrL
SpdGainThrH
SpdRegHLim
SpdRegLLim
SRegLimFkSrc
V/F Curve Type
Maximum output voltage
Base frequency
V/F intermediate voltage
V/F intermediate frequency
Maximum output frequency
Minimum output frequency
Slip compensation
Time constant of slipcompensation
Torque boost level
Boost level source
Automatic boost functionenabling
Magnetizing currentregulator gain
Damping gain
Speed loop proportionalgain (low speed)
Speed loop integral gain(low speed)
Speed loop proportionalgain (high speed)
Speed loop integral gain(high speed)
Speed loop gain schedulinglow threshold
Speed loop gain schedulinghigh threshold
Speed regulator High limit
Speed regulator Low limit
Speed regulator limitsfactor source
[0] Custom
[1] Linear[2] Quadratic
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3
[0] Disable[1] Enable
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3
V/F curve defined by theuserLinear characteristicQuadratic characteristic
NullAnalog input 1Analog input 2Analog input 3
Automatic boost functiondisabledAutomatic boost functionenabled
NullAnalog input 1Analog input 2Analog input 3
1
(**)
(**)
(**)
(**)
110
0.0
0
0.1
1
0
0
0
0
2.0
1.0
2.0
1.0
0.0
0.0
10.0
-10.0
0
0
50
25
0
1.0
0
0.0
0
0
0
0
0
0
0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
-100.0
0
2
(**)
500
P.061
P.062
110
25.0
250
10
25
3
1
100
100
100.0
100.0
100.0
100.0
100.0
100.0
100.0
0.0
3
V
Hz
V
Hz
% ofF.020
% ofF.020
%
sec
% ofP.061
%
%
%
%
%
% ofF.020
% ofF.020
% ofF.020
% ofF.020
1
0.1
1
0.1
1
0.1
1
0.1
1
0.1
1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
412
413
414
415
416
417
418
419
420
421
422
423
424
425
501
502
503
504
507
508
509
510
511
Slip
Com
p.B
oo
st
Aut
omat
ic F
lux R
egul
atio
nAn
ti Osc
illatio
n fu
nctio
nO
utp.
Fre
q. L
imit
V/F
Cu
rve
Clo
sed
Lo
op
Sp
eed
Co
ntr
ol
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 87
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
P.180
P.181
P.200
P.201
P.202
P.203
P.204
P.205
P.206
P.207
P.220
P.221
P.222
P.223
P.240
P.241
P.242
P.243
P.260
SW clamp enable
Clamp alm HldOff
Ramp Currlim Mode
Accel curr lim
En lim in steady
Curr lim steady
Curr ctrl P-gain
Curr ctrl I-gain
Curr ctr feedfwd
Decel curr limit
En DC link ctrl
DC-lnk ctr Pgain
DC-lnk ctr Igain
DC-link ctr FF
OverTorque mode
OT curr lim thr
OT level fac src
OT signal delay
Motor OL prot en
Current clamp enable
Hold off time for the currentclamp alarm
Enable current limitationduring ramp
Current limit in accelerationphase
Enable current limitation insteady state
Current limit at constantspeed
Current limiter proportionalgain
Current limiter integral gain
Current limiter feed-forward
Current limit in decelerationphase
Stall prevention during dec.for overvoltage
DC link voltage limiterproportional gain
DC link voltage limiterintegral gain
DC link voltage limiter feed-forward
Overtorque mode
Current limit for overtorque
Overtorque level factorsource
Delay time for overtorquesignaling
Enabling of motor overloadprotection
[0] Disable[1] Enable
[0] None[1] PI Limitator[2] Ramp freeze
[0] Disable[1] Enable
[0] None[1] PI Limitator[2] Ramp freeze
[0] No Alm,Chk on
[1] No Alm,Chk ss
[2] Alm always
[3] Alm steady st
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3
[0] Disable[1] Enable
NonePI Limit regulatorOn/Off Ramp
NonePI Limit regulatorOn/Off Ramp
0: Overtorque detectionalways active and Over-torque alarm disabled.1: Overtorque detectionin steady state and Over-torque alarm disabled.2: Overtorque detectionalways active and Over-torque alarm enabled.3: Overtorque detectionin steady state and Over-torque alarm enabled.
NullAnalog input 1Analog input 2Analog input 3
1
25.5
0
(*)
0
(*)
10.0
30.0
0
(*)
0
3.0
10.0
0
0
110
0
0.1
1
0
0.0
0
20
0
20
0.1
0.0
0
20
0
0.1
0.0
0
0
20
0
0.1
0
1
25.5
2
(*)
1
(*)
100.0
100.0
250
(*)
2
100.0
100.0
250
3
200
3
25
1
sec
% ofI nom
% ofI nom
%
%
%
% ofI nom
%
%
%
%
sec
0.1
1
1
0.1
0.1
1
1
0.1
0.1
1
1
0.1
426
512
427
428
429
430
431
432
433
494
434
435
436
437
438
439
440
441
444
DC
Lin
k L
imit
SW
Cu
rr.
Cla
mp
Cu
rren
t L
imit
Ove
r To
rqu
e A
larm
Co
nfi
gM
otor
Ove
rload
Con
fig
88 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
P.280
P.281
P.282
P.283
P.300
P.301
P.302
P.303
P.304
P.320
P.321
P.322
P.323
P.324
P.325
P.340
P.341
P.342
P.343
P.360
BU Config
Brake res value
Brake res power
Br res thermal K
DC braking level
DCB lev fac src
DC braking freq
DC braking start
DC braking stop
Autocapturemode
Autocapture Ilim
Demagnetiz time
Autocap f scan t
Autocap V scan t
Autocap spd src
Undervoltage thr
Max pwrloss time
UV alarm storage
UV Trip mode
OV prevention
Braking unit configuration
Ohmic value of brakingresistor
Braking resistor power
Braking resistor thermalconstant
DC braking level
DC braking level factorsource
Frequency for DC brakingenabling
DC braking time at start
DC braking time at stop
Flying restart mode
Catch on flight current limit
Demagnetization minimuntime
Frequency scanning timeduring Pick Up
Voltage scanning timeduring Pick Up
Source of the referencefor Pick Up function
Undervoltage threshold
Restart time fromundervoltage
Enabling of undervoltagealarm storage
Undervoltage tripping mode
Automatic PickUp enablingafter Overvoltage
[0] BU disabled[1] BU en OL dis
[2] BU en OL en
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3
[0] Disable[1] 1st run only
[2] Always
[0] Frequency ref
[1] Max freq ref
[2] Last freq ref[3] Encoder
[0] Disable[1] Enable
[0] Disabled[1] CoastThrough[2] Emg stop
[0] Disable[1] Enable
BU disabledBU enabled & OverloaddisableBU & Overload enabled
NullAnalog input 1Analog input 2Analog input 3
NullFlying restar at first Runafter power onFlying restart at each Runcommand
From active frequencyreferenceFrom the Max fre refparameter (F.020).From freq. set desiredFrom encoder
Function disabledKinetic energy recoveringEmergency stop mode
1
(*)
(*)
(*)
0
0
0
0
0
0
120
(*)
1
0.2
0
0
0
1
0
0
0
1
0.01
1
0
0
0
0
0
0
20
0.01
0.1
0.1
0
0
0
0
0
0
ohm
kW
sec
% ofI nom
Hz
sec
sec
% ofI nom
sec
sec
V
% ofP.020
sec
2
250
25
250
100
3
500
60
60
2
(*)
10
25
25
3
80
25
1
2
1
1
0.01
1
1
0.1
0.1
0.1
0.01
0.1
0.1
1
0.1
445
446
447
448
449
450
451
452
453
454
456
457
458
459
460
462
463
464
491
465
Au
toca
ptu
re f
un
ctio
nU
nd
ervo
ltag
e C
on
fig
Ove
rvol
tage
C
onfig
BU
Co
nfig
DC
Bra
ke C
on
fig
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 89
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
P.380
P.381
P.382
P.383
P.400
P.410
P.420
P.421
P.422
P.440
P.441
P.442
P.443
P.460
P.461
Autoreset attmps
Autoreset clear
Autoreset delay
Autores flt rly
Ext fault mode
Ph Loss detec en
Volt reduc mode
V reduction fact
V fact mult src
Frequency thr 1
Freq prog 1 hyst
Frequency thr 2
Freq prog 2 hyst
Const speed tol
Const speed dly
Number of autoresetattempts
En. automatic reset ofautorestart attempts
Autoreset time delay
Alarm relay contactsbehaviour during autoreset
External fault detectionmode
Phase Loss detectionenabling
Voltage reduction mode
Output voltage reductionfactor
Source of voltagereduction factor multiplier
Frequency 1 level detection
Hysteresis amplituderelated to P-420
Frequency 2 level detection
Hysteresis amplituderelated to P-422
Tolerance at constantspeed
Ramp end signalling delay
[0] OFF[1] ON
[0] Alm alw,No AR
[1] Alm run,No AR
[2] Alm alw, ARes
[3] Alm run, ARes
[0] Disable[1] Enable
[0] Always[1] Steady state
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3
- Drive in alarm Alarm always active Alarm autoreset is not
possible. - Drive in alarm Alarm active only with
running motor. Alarm autoreset is not
possible. - Drive in alarm Alarm always active Alarm autoreset is
possible. - Drive in alarm Alarm active only with
running motor Alarm autoreset is
possible.
AlwaysCostant speed only
NullAnalog input 1Analog input 2Analog input 3Vo
ltag
e R
edu
ctio
n C
on
fig
0
10
5
1
0
1
0
100
0
0
0.5
0
0.5
0
0.1
0
0
0.1
0
0
0
0
10
0
0
0
0
0
0
0
255
250
50
1
3
1
1
100
3
50
50
50
50
25
25
min
sec
% ofP.061
Hz
Hz
Hz
Hz
Hz
sec
1
0.1
1
0.1
0.1
0.1
0.1
0.1
0.1
466
467
468
469
470
492
471
472
473
474
475
476
477
478
479
Fre
qu
ency
Th
resh
old
Ste
ady
Sta
te S
ign
allin
gE
xter
nal
Fau
lt
Co
nfi
gP
has
e L
oss
Au
tore
set
Co
nfi
g
90 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
P.480
P.481
P.500
P.501
P.502
P.520
P.540
P.560
P.561
P.580
P.600
P.999
Heatsnk temp lev
Heatsnk temp hys
Switching freq
Sw freq reduc en
Min switch freq
Overmod max lev
Out Vlt auto adj
Deadtime cmp lev
Deadtime cmp slp
Startup display
Speed dsply fact
Param prot code
Heatsink temperaturesignalling level
Hysteresis band related toP.480
Modulation frequency
Enabling of switchingfrequency reduction
Overmodulation level
Overmodulation level
Automatic adjustment ofoutput voltage
Dead times compensationlimit
Dead times compensationslope
IPA of the parameter to bedisplayed at power on
Speed conversionconstant for display
Parameters protectioncode
70
5
(*)
0
(*)
0
1
(*)
(*)
1
1
0
10
0
P.502
0
0
0
0
0
0
1
0.01
0
110
10
(*)
1
P.500
100
1
255
255
1999
99.99
3
480
481
482
483
495
484
485
486
487
488
489
490
Dea
d Ti
me C
omp.
Dis
play
Set
tings
Pro
tect
ion
Stopped motor: possibilityto write all parameters.Running motor: someparameters are writingprotected (IPA in bold)
All parameters are writingprotected excepted:- F000, F100..F116,multispeed functionparameters- P999 Param prot code- C000 Save parameter (*)- C020 Alarm clear- H500..H511, serial linecommands.
All parameters are writingprotected excepted:- P999 Param prot code- C000 Save parameter (*)- C020 Alarm clear- H500..H511, serial linecommands.
Stopped motor: possibilityto write all parameters.Running motor: someparameters are writingprotected (IPA in bold)Possibility to executeSave parameter also withrunning motor.
1
1
1
0.01
Hea
tsin
k Tem
p. T
hres
hold
PW
M S
etti
ng
s
[0] 1kHz[1] 2kHz[2] 3kHz[3] 4kHz[4] 6kHz[5] 8kHz[6] 10kHz[7] 12kHz[8] 14kHz[9] 16kHz[10] 18kHz
[0] Disable[1] Enable
As P.500
0 Protectiondisabled
1 Protectionenabled
(*) = only withmotor stopped
2 Protectionenabled
(*) = only withmotor stopped
3 Protectiondisabled
°C
°C
%
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 91
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
APPLICATIONA.000
A.001
A.002
A.003
A.004
A.005
A.006
A.007
A.008
A.050
A.051
A.052
A.053
A.054
A.055
A.056
A.057
A.058
A.059
PID mode
PID ref sel
PID fbk sel
PID digital ref
PID activat mode
PID-Encoder sync
PID err sign rev
PIDInteg init en
PID update time
PID Prop gain 1
PID Int tconst 1
PID Deriv gain 1
PID Prop gain 2
PID Int tconst 2
PID Deriv gain 2
PID high limit
PID low limit
PID max pos err
PID min neg err
PID mode
PID reference selector
PID feedback selector
PID digital reference
PID active in steady stateonly
Enabling of encoder / PIDsynchronism
Error sign reversal
Integral term initialization atstart
PID updating time
Proportional term gain 1
Integral action time 1
Derivative action time 1
Proportional term gain 2
Integral action time 2
Derivative action time 2
PID output upper limit
PID output lower limit
PID max. positive error
PID max. negative error
[0] Disable[1] Freq sum
[2] Freq direct
[3] Volt sum
[4] Volt direct
[5] Stand alone
[6] St-Al always
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3[4] Frequency ref[5] Ramp output[6] Digital ref[7] Encoder freq
[0] Null[1] Analog inp 1[2] Analog inp 2[3] Analog inp 3[4] Encoder freq[5] Output curr[6] Output torque[7] Output power
[0] Always[1] Steady state
[0] Disable[1] Enable
[0] Disable[1] Enable
[0] Disable[1] Enable
NullPID out in sum with rampout ref (Feed forward)PID out not in sum withramp out ref (no Feedforward)PID out in sum withvoltage ref from V/fcurve (Feed forward)PID out not in sum withvoltage ref from V/fcurve (no Feed forward)PID function as genericcontrol (only with drive inRUN)PID function as genericcontrol (any drive status)
NullAnalog input 1Analog input 2Analog input 3Frequency referenceRamp outputInternal referenceEncoder frequency
NullAnalog input 1Analog input 2Analog input 3Encoder frequencyOutput peak currentOutput torqueOutput power
0
0
0
0
0
0
0
0
0
0
99.99
0
0
99.99
0
100
-100
5
5
0
0
0
--100
0
0
0
0
0
0
0
0
0
0
0
-100
-100
0.1
0.1
6
7
7
100
1
1
1
1
2.5
99.99
99.99
99.99
99.99
99.99
99.99
100
100
100
100
%
sec
%
%
%
%
1200
1201
1202
1203
1204
1205
1206
1207
1208
1209
1210
1211
1212
1213
1214
1215
1216
1217
1218
PID
Set
tin
gs
0.1
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.1
0.1
0.1
0.1
PID
Gai
ns
PID
Lim
its
92 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
A.300
A.301
A.302
A.303
A.304
A.305
A.306
A.307
A.308
A.309
A.310
A.311
A.312
A.313
A.314
A.315
AND1 In 1 src
AND1 In 2 src
AND2 In 1 src
AND2 In 2 src
AND3 In 1 src
AND3 In 2 src
OR1 In 1 src
OR1 In 2 src
OR2 In 1 src
OR2 In 2 src
OR3 In 1 src
OR3 In 2 src
NOT1 In src
NOT2 In src
NOT3 In src
NOT4 In src
Set up input block AND1
Set up input block AND1
Set up input block AND2
Set up input block AND2
Set up input block AND3
Set up input block AND3
Set up input block OR1
Set up input block OR1
Set up input block OR2
Set up input block OR2
Set up input block OR3
Set up input block OR3
Set up input block NOT1
Set up input block NOT2
Set up input block NOT3
Set up input block NOT4
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
As for I.100
49
49
49
49
49
49
49
49
49
49
49
49
49
49
49
49
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
77
77
77
77
77
77
77
77
77
77
77
77
77
77
77
77
1355
1356
1357
1358
1359
1360
1361
1362
1363
1364
1365
1366
1367
1368
1369
1370
Pro
gra
mm
ab
le L
og
ic
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 93
IPA
CODE LCD DISPLAY
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
UN
IT
VA
RIA
TIO
N
COMMANDC.000
C.001
C.002
C.020
C.040
C.041
C.070
C.071
C.100
Save parameters
Recall param
Load default
Alarm clear
Recall key prog
Save pars to key
Recal kbg prog
Save pars to kbg
Measure stator R
Save parameters command
Recall last set of savedparameters
Recall of the factoryparameters.
Reset of the the Alarm Listregister
Recall of the parameters inthe external key
Storage of the inverterparameter on the externalkey
Recall of parameters fromLCD keypad
Storage of parameters intoLCD keypad
Motor Autotune command
(1)
(2)
(1)
(2)
(1)
(2)
(1)
(2)
(1)
(2)
(1)
(2)
(1)
(2)
(1)
(2)
(1)
(2)
No action.
Save parameterscommand.
No action.
Recall last set of savedparameters.
No action.
Load default parameters.
No action.
Clear alarm registercommand.
No action.
Recall parameter fromPRG-KEY key.
No action.
Storage of parameters toPRG-KEY key.
No action.
Recall pars from keypad
No action.
Store pars into keypad
No action.
Autotune command.
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(1)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
(2)
800
801
802
803
804
805
809
810
806
Bas
icA
larm
Re
se
tE
xter
nal
Key
Tun
ing
(1) : AGy-4A, AGy-5 = Confirm? NOAGy-4 = off
(2) : AGy-4A, AGy-5 = Confirm? YESAGy-4 = do
LCD
key
pad
94 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
IPA
CODE
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
HIDDEN
H.000
H.001
H.010
H.011
H.020
H.021
H.022
H.025
H.026
H.027
H.030
H.031
H.032
H.033
H.034
H.040
H.050
H.052
H.054
H.056
H.058
H.060
H.062
Virtual digital command
Exp virtual digital command
Virtual digital state
Exp Virtual digital state
Virtual An Output 1
Virtual An Output 2
Exp Virtual An Output 1
Virtual analog input 1
Virtual analog input 2
Virtual analog input 3
Profidrive Control word (see Profibusinstruction manual)
Profidrive Status word (see Profibusinstruction manual)
Profidrive reference (see Profibusinstruction manual)
Profidrive actual reference (see Profibusinstruction manual)
Drive status
Progress
Drive output frequency at 32bit (LSW) (d.000)
Drive reference frequency at 32bit (LSW) (d.001)
Output speed (d.000)*(P.600) at 32bit (LSW) (d.007)
Speed Ref (d.001)*(P.600) at 32bit (LSW) (d.008)
Encoder freq at 32bit (LSW) (d.301)
Encoder speed (d.000)*(P.600) at 32bit (LSW)(d.302)
Bitwise reading of active alarms (32 bits).Each bit is associated to a specific alarm,according to table 9.3.1.
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
-32768
-32768
-32768
-32768
-32768
-32768
0
0
-16384
-16384
0
0
- 2 31
- 2 31
- 2 31
- 2 31
- 2 31
- 2 31
2 32 -1
255
255
255
255
32767
32767
32767
32767
32767
32767
65535
65535
16383
16383
65535
100
2 31 -1
2 31 -1
2 31 -1
2 31 -1
2 31 -1
2 31 -1
2 32 -1
1000
1001
1002
1003
1004
1005
1006
1082
1083
1084
1007
1008
1040
1041
1042
1009
1010
1012
1014
1016
1018
1044
1060
Vir
tual
I/O
s C
om
man
ds
Pro
fid
rive
Pro
file
Dri
ve S
tatu
sP
aram
eter
s R
ead
ing
Ext
ensi
on
This menu is not available on thekeypad. The setting and the reading ofthe parameters here contained, can beperformed exclusively via serial line orthrough SBI card.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 95
IPA
CODE
PARAMETER PICK LIST
DESCRIPTION [CODE]LCD SELECTION
DESCRIPTION DEF
AU
LT
MIN
MA
X
H.100
H.101
H.110
H.111
H.120
H.121
H.130
H.131
H.500
H.501
H.502
H.503
H.504
H.505
H.506
H.507
H.508
H.509
H.510
Remote Digital Inputs (0..15)
Remote Digital Inputs (16..31)
Remote Digital Outputs (0..15)
Remote Digital Outputs (16..31)
Remote Analog input 1
Remote Analog input 2
Remote Analog output 1
Remote Analog output 2
Hardware reset
Alarm reset
Coast to stop
Stop with ramp
Clockwise Start
Anti-clockwise Start
Clockwise Jog
Anti-clockwise Jog
Clockwise Flying restart
Anti-clockwise Flying restart
DC Brake
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-32768
-32768
-32768
-32768
0
0
0
0
0
0
0
0
0
0
0
65535
65535
65535
65535
32767
32767
32767
32767
1
1
1
1
1
1
1
1
1
1
1
1021
1022
1023
1024
1025
1026
1027
1028
1029
1030
1031
1032
1033
1034
1035
1036
1037
1038
1039
Ser
ial
Lin
k C
om
man
ds
Rem
ote
I/O
s C
on
tro
l
96 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
7.2 Menu d - DISPLAY
Basic
d.000 Output frequencyDrive output frequency [Hz].
d.001 Frequency ref (Frequency reference)Drive frequency reference [Hz] .
d.002 Output currentDrive output current (rms) [A].
d.003 Output voltageDrive output voltage (rms) [V].
d.004 DC link voltageDrive DC Bus voltage (DC) [V].
d.005 Power factorDrive output power factor.
d.006 Power [kW]Drive output active power
d.007 Output speedCalculated speed (d.000 * P.600).
d.008 Speed ref (Speed reference)Calculated speed reference (d.001 * P.600).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.000 Output frequency Hz 0.01 001
d.001 Frequency ref Hz 0.01 002
d.002 Output current A 0,1 003
d.003 Output voltage V 1 004
d.004 DC link voltage V 1 005
d.005 Power factor 0.01 006
d.006 Power [kW] kW 0.1 007
d.007 Output speed 0.01 / 1 008
d.008 Speed ref 0.01 / 1 009
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 97
Overload
d.050 Heatsink temp (Heatsink temperature)Drive heatsink temperature [°C].
d.051 Drive OL (Drive overload level)The drive overload control function is based on a I2t, that allows for the IEC 146 class 2 service.The I2t integrator level can be read in d.051, and is calculated as follows:
d.051[%] = KOL
x ∫(I2out
- I2CONT
)
Dove:
Iout Inverter output current;
ICONT Inverted rated output current level, IEC 146 class 1 (see table 3.3.3.1), calculated taking intoaccounts all applicable deratings (see Table 3.3.2.1).
KOL I2t integration constant, calculated in order to obtain d.0.51 = 100%, after operating for 60s with
Iout = 1.36 x ICONT.
Overload time and restore time for different current levels are reported in the following figures:
Figure 7.2.1: Overload Time Figure 7.2.2: Pause Time
NOTE! A short overload of 200% of the inverter rated current is allowed for 0.5s.
The I2t logic acts on the limits of the inverter output current. During normal operation, instantaneous value of theinverter output current can reach 200% of inverter rated. After 0.5s at 200%, the output current limit is reduced to150%. When the overload level d.051 reaches 100%, the output current limit is reduced to 100% of inverter rated,and stays there until the overload integrator is completely discharged. At this point, the original limit of 200% isresumed.
NOTE! If active current limiters (see P200, P202) and current clamp (see P.180) are all disabled, the drive is notable to protect himself against excessive output current and will trip for overload as soon as the integratorreaches 100%.
Status of the overload function can be monitored on any digital output of the drive, programmed as follows (seeChap. 7.4, section Digital Inputs Regulation Board):
[46] Drv OL status Digital output is set when the integrator d.051 reaches 100%, and is reset when theintegrator is completely discharged.
[47] Drv OL warn Digital output is set when the integrator d.051 is equal or above 90%, and is resetotherwise.
98 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
d.052 Motor OL (Motor overload)Motor overload level (100% = alarm threshold).
d.053 Brake res OL (Brake resistror overload)Braking resistor overload level (100%=alarm thr).
d.054 Reserved
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.050 Heatsink temp °C 1 010
d.051 Drive OL % 0.1 011
d.052 Motor OL % 0.1 012
d.053 Brake res OL % 0.1 013
d.054 Reserved 058
Inputs/Outputs
d.100 Dig inp status (Digital inputs status)Status of the digital inputs acquired by the drive. Each of the inputs can come either from regulation boardterminal , from optional field bus card or from serial line. See figure 7.4.8 .According to the type of keypad in use, the status of digital inputs will be displayed as follows:
Reset
Hz A VPrg Rev Fwd
Prg
Dig inp status
Digital input 1 = ON
Digital input 5 = ON
_ _ _ 5 _ _ _ 1
Hz A VPrg Rev Fwd
. I. . I.
Digital input 2 = OFF
Digital input 1 = ON
Digital input 3 = OFF
Digital input 4 = OFF
Digital input 8 = OFF
Digital input 7 = OFF
Digital input 6 = OFF
Digital input 5 = ON
d.101 Term inp status (Terminal inputs status)Status of the digital inputs terminal of the drive regulation board.
See example d.100
d.102 Vir dig inp stat (Virtual digital inputs status)Status of the virtual digital inputs received by serial link or field bus card, by writing parameter H.000.
See example d.100
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 99
d.120 Exp dig inp stat (Expansion board digital inputs status)Status of the expansion digital inputs acquired by the drive. Each of the inputs can come either from regulationboard terminal , from optional field bus card or from serial line. See figure 7.4.8 .According to the type of keypad in use, the status of expansion digital inputs will be displayed as follows:
Res
et
Hz A VPrg Rev Fwd
Exp Dig inp stat
Exp Digital input 4 = OFF
Exp Digital input 1 = ON
Exp Digital input 3 = ON
_ 3 _ 1
Hz A VPrg Rev Fwd
I. I.
Exp Digital input 2 = OFF
Exp Digital input 1 = ON
Exp Digital input 3 = ON
Exp Digital input 4 = OFF
d.121 Exp term inp (Expansion board terminal inputs status)Status of the expansion digital inputs terminal of the drive expansion board.
See example d.120
d.122 Vir exp dig inp (Expansion Board virtual digital inputs status)Status of the expansion virtual digital inputs received by drive serial link or field bus card, by writingparameter H.001.
See example d.120
d.150 Dig out status (Digital outputs status)Status of the digital outputs terminals of the regulation board. Each output can be set by the associated drivefunction (see I.100, ..., I.103) or by writing the parameter H.010 (see figure 7.4.9).According to the type of keypad in use, the status of digital outputs will be displayed as follows:
Res
et
Hz A VPrg Rev Fwd
Dig out status
Digital output 1 = OFF
Digital output 3 = ON
_ 3 _ 1
Digital output 4 = OFF
Hz A VPrg Rev Fwd
I.i .
Digital output 2 = ON
Digital output 1 = OFF
Digital output 3 = ON
Digital output 4 = OFF
d.151 Drv dig out sta (Terminal digital outputs status)Status of the digital outputs set by the drive function programmed by parameters I.100 through I.103.
See example d.150
d.152 Vir dig out sta (Virtual digital outputs status)Status of the virtual digital outputs set via serial link or field bus card, by writing parameter H.010.
See example d.150
100 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
d.170 Exp dig out sta (Expansion board digital outputs status)Status of the expansion digital outputs terminals of the regulation board. Each output can be set by theassociated drive function (see I.150, ..., I.152) or by writing the parameter H.010 (see figure 7.4.9).According to the type of keypad in use, the status of expansion digital outputs will be displayed as follows:
Res
et
Hz A VPrg Rev Fwd
Exp Dig out stat
Exp Digital output 1 = OFF
Exp Digital output 2 = ON
2 _
Hz A VPrg Rev Fwd
I .
Exp Digital output 2 = ON
Exp Digital output 1 = OFF
d.171 Exp DrvDigOutSta (Expansion board terminal outputs status)Status of the expansion digital outputs set by the drive function programmed by parameters I.100 through I.103.
See example d.170
d.172 Exp VirDigOutSta (Expansion board virtual digital outputs status)Status of the expansion virtual digital outputs set via serial link or field bus card, by writing parameter H.010.
See example d.170
d.200 An in 1 cnf mon (Analog input 1 configuration monitor)Monitor of the function associated to the Analog input 1:
[0] Null funct No function programmed[1] Freq ref 1 Frequency reference 1 chapter FREQ & RAMPS, section Reference sources (F.050)[2] Freq ref 2 Frequency reference 2 chapter FREQ & RAMPS, section Reference sources (F.051)[3] Boost lev fac Level of voltage boost chapter PARAMETERS, section Boost (P.121)[4] OT level fact Level of over torque chapter PARAMETERS, section OT level factor src (P.242)[5] V red lev fac Output voltage reduction level chapter PARAMETERS, section Voltage Red Config P.422)[6] DCB level fac DC braking current level chapter PARAMETERS, section DC brake Config (P.301)[7] Ramp ext fact Ramp extension factor chapter PARAMETERS, section Ramp Config (F.260)[8] Freq ref fact Multiplier factor for frequency referencechapter FREQ & RAMP, section F.080[9] SpdPI LimFac Level of speed PI limit chapter PARAMETERS, section Closed Loop Speed Control[10] Mlt frq ch 1 Multi frequency reference 1 chapter FREQ & RAMPS, section Reference sources (F.060)[11] Mlt frq ch 2 Multi frequency reference 2 chapter FREQ & RAMPS, section Reference sources (F.061)
d.201 An in 1 monitor (Analog input 1 monitor)Analog input 1 - block output (%). See Fig. 7.4.1 .
d.202 An in 1 term mon (Analog input 1 terminals monitor)Analog input 1 block input (%). See Fig. 7.4.1 .It monitors the signal at the An In 1 regulation board terminals, according to the value of An inp 1 Type (I.200)parameter:
• selection: [0] +/- 10V: 0V = 0%, -10V = -100%, +10V = +100%
• selection: [1] 0-10V/0-20mA: 0V = 0%, +10V = +100%
d.210 An in 2 cnf mon (Analog input 2 configuration monitor)Monitor of the function associated to Analog Input 2. See param. d.200.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 101
d.211 An in 2 monitor (Analog input 2 monitor)Analog input 2 - block output (%). See figure 7.4.1.
d.212 An in 2 term mon (Analog input 2 terminals monitor)Analog input 2 - block input (%). See Fig. 7.4.1.It monitors the signal at the An In 2 regulation board terminals, according to the value of An inp 2 Type (I.210)parameter:• selection: [0] +/- 10V: 0V = 0%, -10V = -100%, +10V = +100%• selection: [1] 0-10V/0-20mA: 0V = 0%, +10V = +100%
d.220 An in 3 cnf mon (Analog input 3 configuration monitor)Monitor of the function associated to Analog input 3. See param. d.200.
d.221 An in 3 monitor (Analog input 3 monitor)Analog input 3 - block output (%). See Fig. 7.4.1.
d.222 An in 3 term mon (Analog input 3 terminals monitor)Analog input 3 - block input (%). See Fig. 7.4.1.It monitors the signal at the An In 3 regulation board terminals, according to the value of An inp 3 Type (I.220)parameter:
• selection: [1] 0-10V/0-20mA: 0mA = 0%, 20mA = +100%
• selection: [2] 4-20mA: 4mA = 0%, 20mA = +100%
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.100 Dig inp status 014
d.101 Term inp status 015
d.102 Vir dig inp stat 016
d.120 Exp dig inp stat 017
d.121 Exp term inp 018
d.122 Vir exp dig inp 019
d.150 Dig out status 020
d.151 Drv dig out sta 021
d.152 Vir dig out stat 022
d.170 Exp dig out stat 023
d.171 Exp DrvDigOutSta 024
d.172 Exp VirDigOutSta 025
d.200 An in 1 cnf mon 026
d.201 An in 1 monitor % 027
d.202 An in 1 term mon % 028
d.210 An in 2 cnf mon 029
d.211 An in 2 monitor % 030
d.212 An in 2 term mon % 031
d.220 An in 3 cnf mon 032
d.221 An in 3 monitor % 033
d.222 An in 3 term mon % 034
Encoder
d.300 EncPulses/Sample (Encoder Pulses / Sample)Number of encoder pulses, recorded in the time interval defined by parameter I.504.
d.301 Encoder freq (Encoder frequency)Frequency detected by the encoder (Motor electrical frequency) [Hz]
102 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
d.302 Encoder speedSpeed detected by the encoder (d.000 * P.600).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.300 EncPulses/Sample 0.001 035
d.301 Encoder freq Hz 0.01 036
d.302 Encoder speed 0.01 / 1 037
Option
d.350 Option 1 stateIt monitors the status of the optional board 1.
d.351 Option 2 stateIt monitors the status of the optional board 2.
d.353 SBI StateStatus of the communication between SBI optional board (Slave) and Master.
d.354 SBI BaudrateBaudrate of the communication between SBI and Master
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.350 Option 1 state 038
0...3 Reserved4 Data exchange..32 Regulation board error (board type)33 Regulation board error (checksum)34 Regulation board error (board incompatible)..64 Expansion error
65 .. 66 Reserved
d.351 Option 2 state As per d.350 039
d.353 SBI State 0 Wait parametrization 059
1 Wait configuration2 Data exchange
3 Errord.354 SBI Baude rate 0 12 Mbit / s 060
1 6 Mbit / s2 3 Mbit / s3 1.5 Mbit / s4 500 Mbit / s5 187.5 kbit / s6 93.75 kbit / s7 45.45 kbit / s8 19.2 kbit / s
15 unknowk
Pid
d.400 PID referencePID reference signal (%), see figure 7.7.1.
d.401 PID feedbackPID feedback signal (%), see figure 7.7.1.
d.402 PID errorPID error signal (%), see figure 7.7.1.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 103
d.403 PID integr comp (PID integral component)PID integral component (%), see figure 7.7.1.
d.404 PID outputPID output signal (%), see figure 7.7.1.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.400 PID reference % 0.1 041
d.401 PID feedback % 0.1 042
d.402 PID error % 0.1 043
d.403 PID integr comp % 0.1 044
d.404 PID output % 0.1 045
Alarm list
d.800 1st alarm-latestLast alarm stored in the drive alarm list (see paragraph 9.3).
d.801 2nd alarmSecond to last alarm stored in the drive alarm list (see paragraph 9.3).
d.802 3rd alarmThird to last alarm stored in the drive alarm list (see paragraph 9.3).
d.803 4th alarmFourth to last alarm stored in the drive alarm list (see paragraph 9.3).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.800 1st alarm-latest 046
d.801 2nd alarm 047
d.802 3rd alarm 048
d.803 4th alarm 049
Drive Identification
d.950 Drive rated curr (Drive rated current)Drive rated current (dependent on the drive size, main voltage and programmed switching frequency): IEC146Class 1.
d.951 SW version (1/2) (Software version - part 1)Display example: 03.0103 = index of software identification01 = index of software revision (new functions or parameters)
d.952 SW version (2/2) (Software version - part 2)Display example: 00.0000 = index of revision (fixing bugs)00 = index of identification (special version)
NOTE! to be considered as reference for SIEI personell
d.953 Power ident code (Power identification code)Reserved.
104 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
d.954 Param ident code (Parameters identification code)Reserved.
d.955 Regul ident code (Regulation identification code)Reserved.
d.956 Startup id code (Startup identification code)Reserved.
d.957 Drive sizeDrive size code.
d.958 Drive cfg typeDrive configuration type: 0 = 400Vac/50Hz, 1 = 460 or 575Vac / 60Hz.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.950 Drive rated curr 0,1 050
d.951 SW version (1/2) 0,01 051
d.952 SW version (2/2) 0,01 052
d.953 Power ident code 053
d.954 Param ident code 054
d.955 Regul ident code 055
d.956 Startup id code 056
d.957 Drive size 0 0.75kW - 230/400/460V 130 2.0Hp - 575V
1 1.5kW - 230/400/460V 131 3.0Hp - 575V
2 2.2kW - 230/400/460V 132 5.0Hp - 575V
3 3kW - 230/400/460V 133 7.5Hp - 575V
4 4kW - 230/400/460V 134 10Hp - 575V
5 5.5kW - 230/400/460V 135 15Hp - 575V
6 7.5kW - 230/400/460V 136 20Hp - 575V
7 11kW - 230/400/460V 137 25Hp - 575V
8 15kW - 230/400/460V 138 30Hp - 575V
9 22kW - 230/400/460V 139 40Hp - 575V
10 30kW - 230/400/460V 140 50 Hp - 575V
11 37kW - 230/400/460V 141 60Hp - 575V
12 45kW - 230/400/460V 142 75Hp - 575V
13 55kW - 230/400/460V 143 100Hp - 575V
14 75kW - 230/400/460V 144 125Hp - 575V
15 90kW - 230/400/460V 145 150Hp - 575V
16 110kW - 230/400/460V 146 200Hp - 575V
17 132kW - 230/400/460V
18 160kW - 230/400/460V
21 18.5kW - 230/400/460V
25 200kW - 230/400/460V
d.958 Drive cfg type 0 400Vac 061
1 460 o 575Vac
Utility
d.999 Display TestDrive display test. On the 7-seg display, all the segments should be on.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
d.999 Display Test Drive display test 099
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 105
7.3 Menu S - START-UP
NOTE! The START UP menu is a set of parameters and functions that allows a quick start of the motor.Theseparameters are actually links to a selection of parameters present in other menus. Therefore, avymodification on a parameter in the START-UP menu is also reflected on the linked parameter found on adifferent menu, and vice-versa.
Power Supply
S.000 Mains voltage (linked to P.020)Rated value of the AC input mains line to line voltage [V].The undervoltage trip function is based on this value (see chapter PARAMETERS, section Undervoltageconfiguration).
S.001 Mains frequency (linked to P.021)Rated value of the AC input mains frequency [Hz].
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
S.000 Mains voltage - 230, 380, 400, 420, 440, 460, 480 (****) 230 575 V 404
(Only for "AGy...-4")
- 500, 575 (Only for "AGy...-5")
S.001 Mains frequency 50 (****) 50 60 Hz 405
60
(****) parameter value dependent on drive type.
V/F Characteristic
S.100 Max out voltage (Maximun output voltage) (linked to P.061)Maximum value of the voltage applied to the motor (normally set as the nameplate, see figure 7.3.2).
S.101 Base frequency (linked to P.062)Rated frequency of the motor (given on the nameplate, see figure 7.3.2)It is the frequency at which the inverter output voltage reaches the Max out voltage (S.100).
S.100
(S.101)
(S.201)
F(n)
V
S.100
S.101 S.201 F(n)
V
Figure 7.3.1: V/F Characteristic
NOTE! For further setting of the V/F characteristic, see the chapter PARAMETERS, section V/F Curve
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
S.100 Max out voltage (**) 50 (**) V 1 413
S.101 Base frequency (**) 25 500 Hz 0,1 414
(**) parameter value dependent on drive nominal mains voltage and mains frequency.
106 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Motor Data
S.150 Motor rated curr (Motor rated current) (linked to P.040)Rated current of the motor at rated kilowatt/horsepower and voltage (given on the nameplate, see figure7.3.2).
In case of control with multiple motors, enter a value equal to the sum of the rated currents of all the motors.Do not perform any self tune.
S.151 Motor pole pairs (linked to P.041)Pole pairs of the motor.Starting from nameplate data, the number of pole pairs is calculated as follows:
P =60 [s] x f [Hz]
nN [rpm]
where: p = motor pole pairsf = rated frequency of the motor (S.101)n
N = rated speed of the motor (see figure 7.3.2).
3 kW
Motor: 3 phase
1420 rpm
Motor & Co.
Type: ABCDE
400 V
IP54
Made in ..............
6.7 A
IEC 34-1 / VDE 0530
Iso Kl F
Nr. 12345-91
S1
50 Hz
Power factor 0.8
S.150 (P.040)
S.152 (P.042)
S.101 (P.062) S.100 (P.061)
I nomRated voltage
Rated power
Rated speed (n )N
2 Hp
Motor: 3 phase
1750 rpm
Motor & Co.
Type: ABCDE
575 V
IP54
Made in ..............
2 A
IEC 34-1 / VDE 0530
Iso Kl F
Nr. 12345-91
S1
60 Hz
Power factor 0.83
S.150 (P.040)
S.152 (P.042)
S.101 (P.062) S.100 (P.061)
I nomRated voltage
Rated power
Rated speed (n )N Efficiency 86.5
Figure 7.3.2: Motor Nameplate (Example: kW rating for 400V motor and Hp rating for 575V motor)
Example: calculation of the pole pairs of a motor having data shown in the above 400V label:
p [polepairs] = = = 2.160 [s] x f [Hz]
n [rpm]N
60 [s] x 50 [Hz]
1420 [rpm]
the value to be set in the parameter S.152 is "2"
S.152 Motor power factor (linked to P.042)Motor power factor in rated condition (given on the nameplate, see figure7.3.2).
S.153 Motor stator R (Motor stator Resistance) (linked to P.043)Ohmic value of the stator resistance of the motor.This value will be automatically updated, by performing the self tune procedure.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
S.150 Motor rated curr (*) (*) (*) A 0.1 406
S.151 Motor pole pairs (*) 1 60 407
S.152 Motor power fact (*) 0.01 1 0.01 408
S.153 Motor stator R (*) 0 99.99 ohm 0.01 409
(*) parameter value dependent on drive size.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 107
Commands & Referencies
S.200 Cmd source sel (Command source selection) (linked to P.000)It defines the source of the main commands (START and STOP) and auxiliary commands (REVERSE, ENABLE,DC-BRAKE, etc.).
S.200 = 0 START & STOP via keypad, auxliliary commands via digital input terminals.In this configuration, START and STOP commands are given through the keypad buttons.
START button STOP button
In order to start the motor, the Digital Input 7 (terminal 5), factory programmed as RUN, must be asserted.If the Digital input programmed as RUN is not active, the motor will STOP with the deceleration ramp time in use.All auxliliary commands are given via digital input terminals.
S.200 = 1 START & STOP and auxliliary commands via digital input terminals.In this configuration, all drive commands are given through the digital input terminals.By default, The START command i given by asserting the Digital Input 7 (terminal 5), factory set asRUN, while the STOP command is given by de-asserting the same Digital Input.It is possible to use several other configurations for giving START, STOP and REV commands fromdigital input terminals. See chapter PARAMETERS, section Commads, for details.
NOTE! At power on, the motor will not start until a positive transition is seen on the Digital Input programmed asRUN (edge sensitive). See description of parameter P.003 for further details.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
S.200 = 2 START & STOP and auxliliary commands via terminals or virtual digital inputs.In this configuration, any drive command may come either from digital input terminals or from virtualdigital inputs. Virtual digital inputs are used to give commands from serial line or fieldbus. Refer tochapter INTERFACE, section Enabling Virtual I/O, for explanation about the use of virtualcommands.
NOTE! At power on, the motor will not start until a positive transition is seen on the Digital Input programmed asRUN (edge sensitive). See description of parameter P.003 for further details.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
S.200 = 3 START & STOP and auxiliary commands via serial line.All drive commands are given through via serial line or filedbus, by using dedicated commands. Referto chapter HIDDEN, section Commands, for a complete description of the available commands.
NOTE! No interlock from digital input terminals is provided, when using commands from serial line.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
P.200 = 4 START & STOP and auxiliary commands via Profidrive control word.In this configuration, all commands are given through the Profidrive standard control word.The optional ProfiBus SBI card is needed.
NOTE! No interlock from digital input terminals is provided, when using commands from Profidrive.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
108 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
S.201 Max ref freq (Maximum reference frequency) (linked to F.020)It is the maximum allowed value for the frequency reference (absolute value), which ever the source.(See figure 7.5.1).
S.202 Ref 1 Channel (Reference 1 channel) (linked to F.050)It defines the source of the frequency reference 1. By default, the frequency reference is supplied through theparameter S.203.For further details, refer to chapter FREQ & RAMPS, section Reference Source.
S.203 Frequency ref 0 (Frequency reference 0) (linked to F.100)It is the effective frequency reference when S.202 = [3] FreqRefx (default settings).It is possible to set either positive or negative values that do not exceed the setting of S.201.The polarity will determine the direction of rotation of the motor.Regardless of the polarity, the REV command will reverse the direction of rotation.
The maximum settable value is correlated to Max ref freq (S.201).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
S.200 Cmd source sel [0] Keypad 0 0 4 400
[1] Terminals
[2] Virtual
[3] Serial
[4] Control word
S.201 Max ref freq (****) 25 500 Hz 0.1 305
S.202 Ref 1 channel [0] Null 3 0 8 307
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Freq ref x (setting through S.203 or F.100)
[4] Multispeed (setting through F.100…F.116)
[5] Motorpotent (setting through F.000…F013)
[6] Analog inp 3 (setting through I.220…I.224)
[7] Encoder (setting through I.500…I.505)
[8] Profidrive Reference by Profibus
S.203 Frequency ref 0 0 -S.201 S.201 311
(****) parameter value dependent on drive type.
S.300 Acc time 1 (Acceleration time 1) (linked to F.201)The drive is equipped with a ramp generator, in order to avoid abrupt changes in output frequency when thefrequency reference is changed or when the drive is started.Acceleration time S.300 represents the time needed to ramp up the frequency from zero to the maximum valuedefined by “ S.201-Max ref freq” parameter.
S.301 Dec time 1 (Deceleration time 1) (linked to F.202)The drive is equipped with a ramp generator, in order to avoid abrupt changes in output frequency when thefrequency reference is changed or when the drive is started.Deceleration time S.301 represents the time needed to ramp down the frequency from the maximum valuedefined by “S.201-Max ref freq” parameter to zero .
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
S.300 Acc time 1 5 1 999.9 sec 0.1 (***) 329
S.301 Dec time 1 5 1 999.9 sec 0.1 (***) 330
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 109
Functions
S.400 Manual boost [%] (linked to P.120)The resistive impedance of the stator windings causes a voltage drop within the motor, which results in areduction of torque in the lower speed range.Compensation can be made for this effect by boosting the output voltage.
S.201
S.400
S.100
S.101
V
F(n)P.064
Figure 7.3.3: Manual Boost Voltage
The setting is in percentage of the Max out voltage (S.100).
NOTE! When custom V/f shape is selected (P.060 = 0):
P.064 parameter represents the return point of the output voltage, on the linear characteristic of V/fcharacteristic (see figure 7.3.3).
S.401 Auto boost en (Automatic boost enabling) (linked to P.122)By enabling the automatic boost calculation, the drive will optimize the V/f profile in order to obtain constant fluxlevel inside the motor over the whole operating speed range. This will improve torque availability at low speed,increasing the starting torque of the drive. The drive uses the stator resistance of the motor in use (either set inparameter S.153 or measured by the autotuning procedure S.900) and the current measured at the inverteroutput terminals to calculate the necessary voltage boost for the V/f profile.
NOTE! Performance achievable with the automatic voltage boost depends on motor parameters. Therefore, inorder to obtain best performance, motor nameplate data should be set correctly and the stator resistancevalue should be measured by running the autotuning procedure.
NOTE! Automatic boost calculation must be disabled when multiple motors are connected to a single inverter.
In some applications, it can be necessary to overflux the machine in order to obtain even more starting torque. Inthose cases, the manual boost (set by S.400) can be used in conjunction to the automatic boost. The resultingvoltage boost will be the sum of the two contributions.
S.450 Slip compensat (Slip compensation) (linked to P.100)When an induction motor is loaded, the mechanical speed of the shaft varies due to the electrical slip betweenstator and rotor quantities which is responsible for the generation of torque.In order to keep the shaft speed constant, the slip compensation function of the drive can be used.The compensation is performed by varying the inverter output frequency of an amount that is calculated frominverter output current and motor parameters. therefore, in oder to obtain best results, motor nameplate data hasto be properly set, and the correct value of the stator resistance (S.153) has to be either edited or measured byself-tuning (S.901). Tuning of the slip compensation function is performed by editing the parameter S.450. IfS.450 = 0.0 (default), the slip compensation assumes the nominal value, calculated from nameplate data.
NOTE! The Slip compensation must be disabled when a multiple motor connection is being used.
110 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
S.451 Slip comp filter (Slip compensation filter) (linked to P.101)It is the response time (in seconds) of the slip compensation function.The lower the setting of this parameter, the quicker will be the response od slip compensation. However, settingtoo low may give rise to undesired oscillations of the speed after sudden load variations.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
S.400 Manual boost [%] 1.0 0.0 25.0 % of S.100 0.1 421
S.401 Auto boost en [0] Disable 0 0 1 423
[1] Enable
S.450 Slip compensat 0 250 10 % of S.101 1 419
S.451 Slip comp filter 0.1 0 10 sec 0.1 420
Utility
S.900 Measure stator R (Measurement of stator resistance)It measures the stator resistance of the motor connected.A correct value of the motor parameters will optimize drive performance in terms of torque availability and speedcontrol, when using Automatic boost (P.401) and Slip compensation (P.450).
Do not perform any tune when a multiple motor connection is being used.
S.901 Save parametersEvery modification of parameter value has immediate effect on drive operation, but is not automatically stored inpermanent memoryThe Save parameter command is used to store the set of parameters currently in use in permanent memory.The drive signals the presence of unsaved parameters by blinking the dedicated yellow LED (Prg) on the keypad.When the drive is turned off, all unsaved modifications are lost.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
S.900 Measure stator R (1) (1) (1) (2) 806
(2)
S.901 Save parameters (1) (1) (1) (2) 800
(2)
(1) : AGy-4A, AGy-5 = Confirm? NOAGy-5 = off
(2) : AGy-4A, AGy-5 = Confirm? YESAGy-5 = do
Below, the sequence for executing the Save parameters command is shown. The sequence is also valid forMeasure stator R (S.900) command.
STARTUP S901
Save parameters
E Save parameters
Confirm? NO
ESave parameters
Run
Save parameters
Done
STARTUP S901
Save parameters
Save parameters
Confirm? YES
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 111
7.4 Menu I - INTERFACE
Digital Inputs Regulation Board
I.000 Dig input 1 cfg (Digital input 1 configuration)
I.001 Dig input 2 cfg (Digital input 2 configuration)
I.002 Dig input 3 cfg (Digital input 3 configuration)
I.003 Dig input 4 cfg (Digital input 4 configuration)
I.004 Dig input 5 cfg (Digital input 5 configuration)
I.005 Dig input 6 cfg (Digital input 6 configuration)
I.006 Dig input 7 cfg (Digital input 7 configuration)
I.007 Dig input 8 cfg (Digital input 8 configuration)
The regulation board provides as standard 8 opto-coupled digital inputs. A PNP or NPN logic level, can be selectedaccording to figure 5.5.1.2. Every input is programmable with a specific code and function, as shown in the list below.
DIGITAL INPUTS SELECTION LIST:
Code LCD displayDescription
0 None Not active1 Run RUN command for the motor START2 Reverse Speed REVERSE command. See paragraph 7.6, P.001.3 Ext Fault NO External fault with NO (Normal Open) contact. See paragraph 7.6, P.400.4 Ext Fault NC External fault with NC (Norm. Closed) contact. See paragraph 7.6, P.400.5 Alarm reset Alarm reset command. See paragraph 9.2 .6 Jog JOG frequency reference enabling. See paragraph 7.5, F.116.7 Freq sel 1 Binary selection for Multispeed. See paragraph 7.5, F.100 ... F.115.8 Freq sel 2 Binary selection for Multispeed. See paragraph 7.5, F.100 ... F.115.9 Freq sel 3 Binary selection for Multispeed. See paragraph 7.5, F.100 ... F.115.10 Freq sel 4 Binary selection for Multispeed. See paragraph 7.5, F.100 ... F.115.11 Ramp sel 1 Binary selection for Multiramp. See paragraph 7.5, F.100 ... F.115.12 Ramp sel 2 Binary selection for Multiramp. See paragraph 7.5, F.100 ... F.115.13 Enable NO Drive Enable with NO (Normal Open) contact. See paragraph 7.6, P.004.14 Enable NC Drive Enable with NC (Norm. Closed) contact. See paragraph 7.6, P.004.15 DCBrake en Enabling of the DC braking function. See paragraph 7.6, DC Brake Configuration
section.16 DCBrake Command for execution of DC braking. See paragraph 7.6, DC Brake
Configuration section.17 Autocapture Command for execution of Autocapture. See paragraph 7.6, Autocapture function
section.18 Ramp enable Enabling / Disabling of the Ramp block. See paragraph 7.5 .19 Zero ref Force the frequency reference to zero. See paragraph 7.5 .20 PID enable Enabling of the PID regulation. See paragraph 7.7, PID setting section.21 PID freeze PID freeze command. See paragraph 7.7, PID setting section.22 PID gain sel Selection of the set of PID gains. See paragraph 7.7, PID setting section.23 Motorpot Up Motorpotentiometer reference increasing command. See paragraph 7.5,
Motorpotentiometer section.
112 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
24 Motorpot Dn Motorpotentiometer reference decreasing command. See paragraph 7.5,Motorpotentiometer section.
25 Reset Motorp Reset of Motorpotentiometer reference. See paragraph 7.5, Motorpotentiometersection.
26 Fast stop Emergency stop command (with ramp time F.206). See paragraph 7.5 .27 Zero freq Output frequency forced to zero, following the ramp programmed for Fast stop
(F.206). The inverter will remain enabled even after the frequency has reached thezero value. See paragraph 7.5 .
28 Stop(3wires) STOP (NC) function. Active when P.001 = [2] 3 Wires. See paragraph 7.6, P.001.29 Local/Remote START/STOP commands from keypad (Local) or from the source specified by
P.000 (Remote). See paragraph 7.6, P.000.30 En lim Steady Activate the current regulator to stationary state. See paragraph 7.6, P.202.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.000 Dig input 1 cfg See Digital inputs selection list 7 0 30 100
I.001 Dig input 2 cfg As for I.000 8 0 30 101
I.002 Dig input 3 cfg As for I.000 28 0 30 102
I.003 Dig input 4 cfg As for I.000 6 0 30 103
I.004 Dig input 5 cfg As for I.000 5 0 30 104
I.005 Dig input 6 cfg As for I.000 1 0 30 105
I.006 Dig input 7 cfg As for I.000 1 0 30 106
I.007 Dig input 8 cfg As for I.000 2 0 30 107
Factory settings for digital inputs are as follows:
Dig input 1 cfg (Terminal 22) = 7 Freq sel 1Dig input 2 cfg (Terminal 23) = 8 Freq sel 2Dig input 3 cfg (Terminal 24) = 28 Stop (3Wires)Dig input 4 cfg (Terminal 25) = 6 JOGDig input 5 cfg (Terminal 7) = 5 Alarm resetDig input 6 cfg (Terminal 6) = 13 External fault NODig input 7 cfg (Terminal 5) = 1 RunDig input 8 cfg (Terminal 4) = 2 Reverse
Digital Inputs Expansion Board
I.050 Exp dig in 1 cfg (Expansion digital input 1 configuration)See list associated to I.000, ..., I.007.
I.051 Exp dig in 2 cfg (Expansion digital input 2 configuration)See list associated to I.000, ..., I.007.
I.052 Exp dig in 3 cfg (Expansion digital input 3 configuration)See list associated to I.000, ..., I.007.
I.053 Exp dig in 4 cfg (Expansion digital input 4 configuration)See list associated to I.000, ..., I.007.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.050 Exp dig in 1 cfg As for I.000 0 0 30 108
I.051 Exp dig in 2 cfg As for I.000 0 0 30 109
I.052 Exp dig in 3 cfg As for I.000 0 0 30 110
I.053 Exp dig in 4 cfg As for I.000 0 0 30 111
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 113
Programmable Logic Output
I.070 AND 1 out cfg (AND 1 block output configuration)
I.071 AND 2 out cfg (AND 2 block output configuration)
I.072 AND 3 out cfg (AND 3 block output configuration)
I.073 OR 1 out cfg (OR1 block output configuration)
I.074 OR 2 out cfg (OR 2 block output configuration)
I.075 OR 3 out cfg (OR 3 block output configuration)
I.076 NOT 1 out cfg (NOT 1 block output configuration)
I.077 NOT 2 out cfg (NOT 2 block output configuration)
I.078 NOT 3 out cfg (NOT 3 block output configuration)
I.079 NOT 4 out cfg (NOT 4 block output configuration)See the list of selections associated to standard digital inputs (I.000 ... I.007).For more information see chapter 7.7 (A.300 ... A.315)
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.070 AND 1 out cfg 0 0 30 186
I.071 AND 2 out cfg 0 0 30 187
I.072 AND 3 out cfg 0 0 30 188
I.073 OR 1 out cfg 0 0 30 189
I.074 OR 2 out cfg 0 0 30 190
I.075 OR 3 out cfg 0 0 30 191
I.076 NOT 1 out cfg 0 0 30 192
I.077 NOT 2 out cfg 0 0 30 193
I.078 NOT 3 out cfg 0 0 30 194
I.079 NOT 4 out cfg 0 0 30 195
Digital Ouputs Regulation Board
I.100 Dig output 1 cfg (Digital output 1 configuration)
I.101 Dig output 2 cfg (Digital output 2 configuration)
I.102 Dig output 3 cfg (Digital output 3 configuration)
I.103 Dig output 4 cfg (Digital output 4 configuration)The regulation board provides as standard, 2 static opto-coupled digital outputs in Open Collector configurationand 2 relays with commutation contacts (see figure 5.5.1.1).Every output is programmable with a specific code and function, as shown in the list below.
DIGITAL OUTPUTS SELECTION LIST:
Code LCD display Description0 Drive Ready Drive ready to start1 Alarm state Alarm signalling (Positive logic)2 Not in alarm Alarm signalling (Negative logic)3 Motor run RUN command active or output frequency ≠ 0Hz4 Motor stop RUN command not active and output frequency = 0Hz
114 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
5 REV rotation Counter-clockwise rotation of the motor6 Steady state Motor is running in steady state7 Ramping Acceleration or Deceleration Ramp in progress8 UV running The drive has tripped for UV, and automatic restart is taking place.9 Out trq>thr Output torque higher than the value of P.24110 Current lim Current limit (during ramp or at steady state)11 DC-link lim DC Bus limit12 Limit active General signalling of drive limit condition13 Autocapt run Autocapture in progress14 BU overload Set when the integrator d.054 = 100%, and Reset when d.054 = 0%.15 Neg pwrfact Negative inverter output power factor16 PID err >< PID error is within the limits defined by A.058 and A.05917 PID err>thr PID error is greater than A.05818 PID err<thr PID error is less than or equal to A.05919 PIDer><(inh) PID error is within the limits defined by A.058 and A.059 (*)20 PIDerr>(inh) PID error is greater than A.058 (*)21 PIDerr<(inh) PID error is less than or equal to A.059 (*)22 FWD enc rot Clockwise rotation of the encoder23 REV enc rot Counter-clockwise rotation of the encoder24 Encoder stop Encoder not rotating25 Encoder run Encoder is rotating26 Extern fault Positive logic for Ext. fault alarm signalling27 No ext fault Negative logic for Ext. fault alarm signalling28 Serial TO Serial link communication time out29 freq=thr1 Output frequency within the range defined by P.440 and P.44130 freq!=thr1 Output frequency outside the range defined by P.440 and P.44131 freq>thr1 Output frequency above the values defined by P.440 and P.44132 freq<thr1 Output frequency below the values defined by P.440 and P.44133 freq=thr2 Output frequency within the range defined by P.442 and P.44334 freq!=thr2 Output frequency outside the range defined by P.442 and P.44335 freq>thr2 Output frequency above the values defined by P.442 and P.44336 freq<thr2 Output frequency below the values defined by P.442 and P.44337 HS temp=thr Heatsink temp within the range defined by P.480 and P.48138 HS temp!=thr Heatsink temp outside the range defined by P.480 and P.48139 HS temp>thr Heatsink temp above the threshold defined by P.480 and P.48140 HS temp<thr Heatsink temp below the threshold defined by P.480 and P.48141 Output freq Square wave synchronized with the inverter output frequency42 Out freq x 2 Square wave synchronized with twice the inverter output frequency43 CoastThrough Kinetic energy recovering during mains loss44 EmgStop Emergency stop after mains loss detection.45 DC Braking DC braking in progress46 Drv OL status Set when the integrator d.051 = 100%, and Reset when d.051 = 0%.47 Drv OL warn Set if d.051 is greater or equal to 90%.48 Mot OL state Set when the integrator d.052 = 100%, and Reset when d.052 = 0%.49 False False assume value 050 True True assume value 151 Reserved52 Reserved53 Reserved54 Reserved55 Reserved56 DI 1 State of digital input 157 DI 2 State of digital input 258 DI 3 State of digital input 359 DI 4 State of digital input 460 DI 5 State of digital input 561 DI 6 State of digital input 662 DI 7 State of digital input 763 DI 8 State of digital input 8
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 115
64 Exp DI 1 Digital input 1 expansion state65 Exp DI 2 Digital input 2 expansion state66 Exp DI 3 Digital input 3 expansion state67 Exp DI 4 Digital input 4 expansion state68 AND 1 out Output block AND 1 state69 AND 2 out Output block AND 2 state70 AND 3 out Output block AND 3 state71 OR 1 out Output block OR 1 state72 OR 2 out Output block OR 2 state73 OR 3 out Output block OR 3 state74 NOT 1 out Output block NOT 1 state75 NOT 2 out Output block NOT 2 state76 NOT 3 out Output block NOT 3 state77 NOT 4 out Output block NOT 4 state
(*) see chapter 7.7, section PID Limit.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.100 Dig output 1 cfg See Digital Outputs selection list 0 0 77 112
I.101 Dig output 2 cfg As for I.100 6 0 77 113
I.102 Dig output 3 cfg As for I.100 3 0 77 114
I.103 Dig output 4 cfg As for I.100 1 0 77 115
Factory settings for Digital Outputs are as follows:
Dig output 1 cfg - opto coupled type (Terminal 16) = 0 Drive readyDig output 2 cfg - opto coupled type (Terminal 17) = 6 Steady stateDig output 3 cfg - relay type (Terminal 18 - 19 - 20) = 3 Motor runningDig output 4 cfg - relay type (Terminal 1 - 2 - 3) = 1 Allarm state
Digital Outputs Expansion Board
I.150 Exp DigOut 1 cfg (Expansion Digital Output 1 configuration)See list associated to I.100, ..., I.103.
I.151 Exp DigOut 2 cfg (Expansion Digital Output 2 configuration)See list associated to I.100, ..., I.103.
I.152 Exp DigOut 3 cfg (Expansion Digital Output 3 configuration)See list associated to I.100, ..., I.103.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.150 Exp DigOut 1 cfg See Digital Outputs selection list 0 0 77 116
I.151 Exp DigOut 2 cfg As for I.100 0 0 77 117
I.152 Exp DigOut 3 cfg As for I.100 0 0 77 180
116 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Analog Inputs Regulation Board
The figure below describes the block diagram of the standard "Analog Inputs" of the drive.
10bi
ts+
sign
Con
vert
erS
elec
tion
Ref
.Typ
e
+ +
I204
I214
I224
I200
I210
I220
I201
I211
I221
X
Off
set
I202
I212
I222G
ain
min
I203
I213
I214
Cla
mp
neg
valu
e
0B
ipol
ar
1-2
Uni
pola
r
I200
I210
I220
ToD
rive
Term
inal
LPF
Mon
itor
d202
d212
d222
Mon
itor
d201
d211
d221
I205
I215
I225D
ead
Ban
d
Figure 7.4.1: Analog Inputs
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 117
The regulation board provides as standard 3 analog inputs.
Analog inputs resolution:voltage input setting: 11 bits (10 bits + sign)current input setting: 10 bits
A typical connection is reported in figure 5.5.1.1.
Each analog input can be programmed to execute any of the functions below:
[1] Freq ref 1 Frequency reference 1 chapter FREQ & RAMPS, section Reference sources (F.050)[2] Freq ref 2 Frequency reference 2 chapter FREQ & RAMPS, section Reference sources (F.051)[3] Boost lev fac Level of voltage boost chapter PARAMETERS, section Boost (P.121)[4] OT level fact Level of over torque chapter PARAMETERS, section OT level factor src (P.242)[5] V red lev fac Output voltage reduction level chapter PARAMETERS, section Voltage Red Config P.422)[6] DCB level fac DC braking current level chapter PARAMETERS, section DC brake Config (P.301)[7] Ramp ext fact Ramp extension factor chapter PARAMETERS, section Ramp Config (F.260)[8] Freq ref fact frequency reference factor chapter FREQ & RAMP, section F.080[9] SpdPI LimFac Level of speed PI limit chapter PARAMETERS, section Closed Loop Speed Control[10] Mlt frq ch 1 Multi frequency reference 1 chapter FREQ & RAMPS, section Reference sources (F.060)[11] Mlt frq ch 2 Multi frequency reference 2 chapter FREQ & RAMPS, section Reference sources (F.061)
Programming logic for the Analog Input function is "destination to source".For example, to program an analog input as drive frequency reference, the user needs to properly set theparameter associated to the selection of the source for the frequency reference (F.050 or F.051, as shown infigure 7.5.1).The function currently associated to any of the analog inputs can be monitored through parameters d.200, d.210,d.220.
I.200 An In 1 type (Analog Input 1 type)Setting of the characteristic of Analog Input 1 (voltage input).I.200 = 0 Bipolar -/+10VI.200 = 1 Unipolar +10VI.200 = 2 Not used
I.210 An In 2 type (Analog Input 2 type)Setting of the characteristic of Analog Input 2 (voltage input).I.210 = 0 Bipolar -/+10VI.210 = 1 Unipolar +10VI.210 = 2 Not used
I.220 An In 3 type (Analog Input 3 type)Setting of the characteristic of Analog Input 3 (current input). I.220 = 0 Not usedI.220 = 1 0Ö20mAI.220 = 2 4Ö20mA
I.201 An In 1 offset (Analog Input 1 offset)
I.211 An In 2 offset (Analog Input 2 offset)
I.221 An In 3 offset (Analog Input 3 offset)It is used to add an offset to the characteristic of the related Analog Input.
I.202 An In 1 gain (Analog Input 1 gain)
I.212 An In 2 gain (Analog Input 2 gain)
I.222 An In 3 gain (Analog Input 3 gain)
118 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Gain of the analog input.It is used to amplify or to attenuate the analog signal at the related terminal.
I.203 An In 1 minimum (Analog Input 1 minimun)
I.213 An In 2 minimum (Analog Input 2 minimun)
I.223 An In 3 minimum (Analog Input 3 minimun)It defines the minimum value of the output of the related analog input block (see figure 7.4.3).
I.204 An In 1 filter (Analog Input 1 filter)
I.214 An In 2 filter (Analog Input 2 filter)
I.224 An In 3 filter (Analog Input 3 filter)It is the time costant of the digital filtering performed on the related Analog Input.By using the above described parameters, it is possible to customize the input/output characteristic of eachAnalog input block.Some samples are reported In the figures below.
I.205 An In 1 DeadBand (Analog input 1 dead band)
I.215 An In 2 DeadBand (Analog input 2 dead band)
I.225 An In 3 DeadBand (Analog input 3 dead band)Dead band of the corresponding analog input. When the input at the terminal is below the threshold defined bythe parameter, the output of the Analog input block is kept to zero. Outside the dead band, the output varieslinearly from zero to 100%. (Refer to figure 7.4.5).
AnInp Drive
I.202=2
I.201
100%
5V 10V
I.202=1
AnInp Drive
I.202=2
I.201
100%
10V
I.202=1
AnInpTerminal0 0
50% 100% 100%
AnInpTerminal
Figure 7.4.2: Analog input characteristic with offset and gain
An Inp Drive [%] = I.202 x An Inp [%] + Terminal I.201
AnInp Drive
I.202=2
I.203=50%
100%
10V
I.202=1
0100%
AnInpTerminal
Figure 7.4.3: Analog input characteristic with minimum value, offset and gain (unipolar)
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 119
An Inp Drive [%] = I.203 + x I.202 x An Inp Terminal [%] + I.201100 - I.203
100
AnInp Drive
I.202=2
I.203=50%
100%
10V
I.202=1
- I.203
-100%
-10V-100%
100%0
AnInpTerminal
Figure 7.4.4:Analog input characteristic with minimum value, offset and gain (bipolar)
NOTE! When the analog input reference is set to 0V, an eventual "noise" can cause undesired speed oscillationbetween positive and negative values of I.203 parameter.
An Inp Drive [%] = I.203 x signum I.202 x An Inp [%] + Terminal + x I.202 x An Inp [%] + I.201 I.201Terminal100 - I.203
100
AnInp Drive
AnInp Terminal10V
100%
-10V
-100%
-100%
100%
I.205=50%
I.205=50%
I.202=1
I.202=2
I.202=2
I.202=1
Figure 7.4.5: Analog input characteristic with dead band
[ ][ ]( ) [ ] -×
-
=
205.%205.%205.100
100
205.%0%
IAnInpforIAnInpI
IAnInpfor
AnInpDrive[ ]
120 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.200 An in 1 Type [0] ±10V 1 0 1 118
[1] 0...10V / 0...20mA
I.201 An in 1 offset 0 -99.9 99.9 % 0.1 119
I.202 An in 1 gain 1 -9.99 9.99 % 0.01 120
I.203 An in 1 minimum 0 0 99.99 % 0.01 121
I.204 An in 1 filter 0.1 0.001 0.25 sec 0.001 122
I.205 An In 1 DeadBand 0 0 99.9 % 0.1 182
I.210 An in 2 Type [0] ±10V 0 0 1 123
[1] 0...10V / 0...20mA
I.211 An in 2 offset 0 -99.9 99.9 % 0.1 124
I.212 An in 2 gain 1 -9.99 9.99 0.01 125
I.213 An in 2 minimum 0 0 99.99 % 0.01 126
I.214 An in 2 filter 0.1 0.001 0.25 sec 0.001 127
I.215 An In 2 DeadBand 0 0 99.9 % 0.1 183
I.220 An in 3 Type [1] 0...10V / 0...20mA 1 1 2 128
[2] 4...20mA
I.221 An in 3 offset 0 -99.9 99.9 % 0.1 129
I.222 An in 3 gain 1 -9.99 9.99 % 0.01 130
I.223 An in 3 minimum 0 0 99.99 % 0.01 131
I.224 An in 3 filter 0.1 0.001 0.25 sec 0.001 132
I.225 An In 3 DeadBand 0 0 99.9 % 0.1 184
Analog Outputs Regulation BoardThe figure below, describes the block diagram of the standard Analog Outputs of the drive
+
+
I.301I.311I.351
X
Offset
I.302I.312I.352
Gain
I303I313I353
Analog Output
Freq out abs
(See AnalogOutputs selection list)
012345678::
LPF
I.300 (AN OUT 1)I.310 (AN OUT 2)I.350 (EXP AN OUT)
Time Constant
Figure 7.4.6: Analog Ouputs
The regulation board provides as standard 2 analog outputs.
Analog output resolution: 10 bits
A typical connection is reported in the figure 5.5.1.1.
Both analog outputs, can provide a full scale signal 0V / +10Vdc (absolute and positive) or +/-10Vdc (genericsetting), according to the parameter assigned .
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 121
I.300 Analog out 1 cfg (Analog output 1 configuration)
I.310 Analog out 2 cfg (Analog output 2 configuration)Each output is programmable with a specific code and function, as shown in the list below.
ANALOG OUTPUTS SELECTION LIST:
Code LCD displayDescription
0 Freq out abs Output Frequency, absolute value1 Freq out Output Frequency2 Output curr Output Current3 Out voltage Output Voltage4 Out trq (pos) Output Torque, positive value (negative values are clamped to zero)5 Out trq (abs) Output Torque, absolute value6 Out trq Output Torque7 Out pwr (pos) Output Power, positive value (negative values are clamped to zero)8 Out pwr (abs) Output Power, absolute value9 Out pwr Output Power10 Out PF Output Power Factor11 Enc freq abs Encoder frequency, absolute value12 Encoder freq Encoder frequency13 Freq ref abs Frequency reference, absolute value14 Freq ref Frequency reference15 Load current Load Current16 Magn current Motor Magnetizing Current17 PID output PID regulator output18 DClink volt DC bus capacitors level19 U current Output phase U current signal20 V current Output phase V current signal21 W current Output phase W current signal22 Freq ref fac Frequency reference factor
I.301 An out 1 offset (Analog output 1 offset)
I.311 An out 2 offset (Analog output 2 offset)It is used to add an offset to the related analog output. See figure 7.4.6.
I.302 An out 1 gain (Analog output 1 gain)
I.312 An out 2 gain (Analog output 2 gain)Gain of the analog output.It can be used to amplify or attenuate the input value of the related analog output block. See figure 7.4.6.
122 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
I.303 An out 1 filter (Analog output 1 filter)
I.313 An out 2 filter (Analog output 2 filter)It is the time costant of the digital filtering performed on the related Analog output. See fig.7.4.6.
By using the above described parameters, it is possible to customize the input/output characteristic of eachAnalog output block, as shown below. For brevity, only parameters related to AnOut1 are considered, but thesame applies to Analog output 2.
3V
10V
Internal V
2
-10V
- 5V
1
3
4
5
1 I.301 = 1 I.302 = 1
2 I.301 = 3 I.302 = 1
3 I.301 = -5 I.302 = 1
4 I.301 = 10 I.302 = -1
5 I.301 = 10 I.302 = -2
0V
Figure 7.4.7: Scaling References and Minimum Values
Vout = 10 x x I.302 + I.301 Stp Var
Fs Var
Where:Vout output voltage at board terminalsStp Var actual variable value (units of the variable)Fs Var full scale of the variable (units of the variable)
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.300 Analog out 1 cfg See Analog outputs selection list 0 0 22 133
I.301 An out 1 offset 0 -9.99 9.99 0,01 134
I.302 An out 1 gain 1 -9.99 9.99 0.01 135
I.303 An out 1 filter 0 0 2,5 sec 0.01 136
I.310 Analog out 2 cfg As for I.300 2 0 22 137
I.311 An out 2 offset 0 -9.99 9.99 0.01 138
I.312 An out 2 gain 1 -9.99 9.99 0.01 139
I.313 An out 2 filter 0 0 2.5 sec 0.01 140
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 123
The table below shows the analog outputs scaling.
CODE Variable Full scale value (±10V)0 Freq out abs F.020 x P.080/100 [Hz] (Maximum output frequency)1 Freq out Same as CODE 02 Output curr 2 x D.950 [Arms] (2 x Inverter rated current)3 Out voltage P.061 [Vrms] (Maximum output voltage)4 Out trq (pos) 2 x Motor rated torque [Nm]5 Out trq (abs) Same as CODE 46 Out trq Same as CODE 47 Out pwr (pos) 2 x Motor rated power [W]8 Out pwr (abs) 2 x Motor rated power [W]9 Out pwr 2 x Motor rated power [W]10 Out PF Power factor = 111 Enc freq abs F.020 x P.080/100 [Hz] (Maximum output frequency)12 Encoder freq F.020 x P.080/100 [Hz] (Maximum output frequency)13 Freq ref abs F.020 x P.080/100 [Hz] (Maximum output frequency)14 Freq ref F.020 x P.080/100 [Hz] (Maximum output frequency)15 Load current Same as CODE 216 Magn current Same as CODE 217 PID output 100% of the PID ouput18 DClink volt 990Vdc (AGy 400…460Vac) - 1250Vdc (AGy 575Vac)19 U current Same as CODE 220 V current Same as CODE 221 W current Same as CODE 222 Freq ref fac Factor = 2
Analog Outputs Exp Board
I.350 Exp An out 1 cfg (Expansion analog output 1 configuration)See description of I.300, I.310.
I.351 Exp AnOut 1 offs (Expansion Analog Output 1 offset)See description of I.301, I.311.
I.352 Exp AnOut 1 gain (Expansion Analog Output 1 gain)See description of I.302, I.312.
I.353 Exp AnOut 1 filt (Expansion Analog Output 1 filter)See description of I.303, I.313.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.350 Exp an out 1 cfg As for I.300 3 0 22 141
I.351 Exp AnOut 1 offs 0 -9.99 9.99 0.01 142
I.352 Exp AnOut 1 gain 1 -9.99 9.99 0.01 143
I.353 Exp AnOut 1 filt 0 0 2.5 sec 0.01 144
124 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Enabling Virtual I/OBy using "virtual I/O", it is possible to mix digital inputs actually coming from terminals of the regulation board with astring of virtual digital inputs directly controlled via serial line or fieldbus.
Likewise, it is possible to control some of the drive digital and analog outputs directly from serial line or fieldbus.
It is possible to configure the drive so that some commands come from digital input terminals of the regulation board(terminal digital inputs), while others come from serial line or fieldbus, by writing the dedicated parameters H.000 andH.001 (virtual digital inputs).
The selection between terminals and virtual digital inputs is determined by the binary code written in the maskparameters I.400, I.410.
Digital outputs at the terminals of the regulation board are normally driven by the drive, according to the functionsprogrammed by the parameters I.000 to I.152. However, it is possible to drive any of the digital outputs on the regulationboard directly from serial line or fieldbus, by writing the virtual digital outputs H.010, H.011.
Whether to use the virtual settings or not is determined by mask parameters I.420, I.430.
Using "virtual assignation” the analogical inputs from the terminal board of the regulator board can be combined with thevirtual analogical entries controlled through the serial line or through the bus field.
The analogical output can also be directed directly through the series line or the bus field (virtual analogical outputs).
Mask parameters have to be managed bitwise. Each bit corresponds to a switch, according to the following logic.
Mask Bit i DI i source DO i source
0 Terminal Drive function
1 Virtual Virtual control
VIRTUAL DIGITAL INPUTS CONFIGURATION
Selection logics for digital input is described by the following figure:
DI8
DI6
DI4
DI2
DI7
DI5
DI3
DI1
VI8
VI6
VI4
VI2
VI7
VI5
VI3
VI1
Drive digital input(Terminals)
Virtual digital commands
H.000d.102d.101
I.400Mask
To internal drivedigital commands
I.000 … I.007
Mask bits = 0 DIxx activeMask bits = 1 VIxx active
0 1 0 1 0 1
Bit 7...............................Bit 1 Bit 0
Figure 7.4.8: Virtual digital inputs configuration
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 125
VIRTUAL DIGITAL OUTPUTS CONFIGURATION
Selection logics for digital output is described by the following figure:
IDO4
IDO2
IDO3
IDO1
VO4
VO2
VO3
VO1
Drive logical statesI.103 ........... I.100 Virtual settings
H.010d.152d.151
Terminal drive outputs
Mask bits = 0 DOxx setting activeMask bits = 1 VOxx setting active
DO4
DO2
DO3
DO1
I.420Mask
0 1
Bit 1Bit 3 Bit 0
0 1 0 1
Bit 2
0 1
d.150
Figure 7.4.9: Virtual digital outputs configuration
VIRTUAL ANALOG INPUTS CONFIGURATION
Selection logic for analog inputs is described by the following figure:
IAI2
IAI3
IAI1
VAI2
VAI3
VAI1
Analog inputs (terminals)
d.22
2
To drive inputs
F.050, F.051, F.060, F.061, ...
Mask bits = 0 IAIx value activeMask bits = 1 VAIx value active
I.440Mask
AN2 AN1
0 1 0 1
AN3
0 1
d.21
2
d.20
2
Virtual analog inputs
H.0
27
H.0
26
H.0
25
Figure 7.4.10: Virtual analog inputs configuration
126 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
VIRTUAL ANALOG OUTPUTS CONFIGURATION
Analog outputs at the terminals of the regulation board are normally written by the drive, according to the settings ofparameters I.300, I.310, I.320. However, it is possible to control the analog outputs directly from serial line or fieldbus, bywriting parameters H.020, H.021, H.022 .
Switching between internal and virtual source for analog output is determined by the mask parameter I.450, according tothe following figure
IAO2
IAO1
VAO2
VAO1
From internal driveanalog output funcion
Virtual setting
H.020I.310
Drive analog output(Terminals)
Mask bits = 0 AOxx value activeMask bits = 1 VAOxx value active
Mask I.450
AO2
AO1
I.300 H.021
Bit 1 Bit 0
0 1 0 1
Figure 7.4.11: Virtual analog outputs configuration
Some examples about the programming of basic functions via virtual assignment are given below:
A) DIGITAL INPUTS
Programming example for:
• RUN and REVERSE commands via “virtual mode”
• EXT FAULT command via “terminal”
P.000 = 2 or 4 Function mode enabled
I.400 = 3 bit 0 and bit 1 are high (1) and bit 5 is low (0)
I.000 = 1 RUN (programmed on digital input 1)
I.001 = 2 REVERSE (programmed on digital input 2)
I.005 = 3 EXTERNAL FAULT (programmed on digital input 6)
Writing H.000 = 1 the motor will turn in FORWARD direction
Writing H.000 = 3 the motor will turn in REVERSE direction
Writing H.000 = 0 the motor will STOP
Refer to chapter 7.9 for more information on H.000 parameter.
The EXTERNAL FAULT command will be activated by applying +24Vdc to terminal 6 (Digital input 6).
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 127
B) DIGITAL OUTPUTS
Programming example for:
• ALARM STATE signalling on Digital output 1
• VIRTUAL SETTING on Digital output 2
I.420 = 2 bit 1 is high (1) and bit 0 is low (0)
I.100 = 1 ALARM STATE (programmed on digital output 1)
I.101 = X ANY SELECTION (programmed on digital output 2)
Digital output 1 active in accordance with the drive alarm status
Digital output 2 active if bit 1 of H.010 = 1
not active if bit 1 of H.010 = 0
C) ANALOG INPUT
Programming examples for:
• Reference Channel 1 Analog entry 1 Terminal board.
• Reference Channel 2 Virtual analog input 2
F.050 = 1 Freq ref 1 Programmed in analog input 1
F.051 = 2 Freq ref 2 Programmed as analog input 2
I.440 = 2 Bit 1 is "high" (1) and Bit 2 is "low" (0)
Writing H.026 = +32767 Freq ref 2 = F.020
Writing H.026 = +0 Freq ref 2 = 0
D) ANALOG OUTPUTS
Programming example for:
• OUTPUT FREQUENCY signalling on Analog output 1
• VIRTUAL SETTING on Analog output 2
I.450 = 2 bit 1 is high (1) and bit 0 is low (0)
I.300 = 0 OUTPUT FREQUENCY (programmed on analog output 1)
I.310 = X ANY SELECTION (programmed on analog output 2)
Analog output 1 signal proportional to the OUTPUT FREQUENCY of the drive
Analog output 2 signal proportional to the setting of H.021
H.021: + 32767 output = +10V
H.021: - 32767 output = - 10V
128 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
I.400 Inp by serial enBitwise mask parameter for virtual digital input. The state of each one of the bits in this mask determines if thecorresponding digital input function of the drive (programmed by I.000 ... I.007) has to be associed to the virtualdigital input or to the terminal digital input. The value which must be assigned to the mask is the equivalentdecimal of the binary code defined by the state of each switch, according to the following:
Mask: = 1 Bit 0 = 1 Virtual input 1 enabling= 2 Bit 1 = 1 Virtual input 2 enabling= 4 Bit 2 = 1 Virtual input 3 enabling= 8 Bit 3 = 1 Virtual input 4 enabling= 16 Bit 4 = 1 Virtual input 5 enabling= 32 Bit 5 = 1 Virtual input 6 enabling= 64 Bit 6 = 1 Virtual input 7 enabling= 128 Bit 7 = 1 Virtual input 8 enabling
Example: if we want to use virtual input 3 and virtual input 6, the value to be written to the mask is (4 + 32) = 36.
I.410 Exp in by ser en (Enabling of Expansion inputs via serial line)Bitwise mask parameter for expansion virtual digital input. The state of each one of the bits in this maskdetermines if the corresponding digital input function of the drive (programmed by I.050 ... I.053) has to beassocied to the expansion virtual digital input or to the expansion board digital input terminal. The value whichmust be assigned to the mask is the equivalent decimal of the binary code defined by the state of each switch,as described for parameter I.400.
I.420 Out by serial en (Enabling of Outputs via serial line)Bitwise mask parameter for virtual digital output. The state of each one of the bits in this mask determines if thecorresponding digital output terminal of the regulation board is controlled by the drive function (programmed byI.100 ... I.103) or by the virtual digital output. The value which must be assigned to the mask is the equivalentdecimal of the binary code defined by the state of each switch, according to the following:
Mask: = 1 Bit 0 = 1 Virtual output 1 enabling= 2 Bit 1 = 1 Virtual output 2 enabling= 4 Bit 2 = 1 Virtual output 3 enabling= 8 Bit 3 = 1 Virtual output 4 enabling
Example: if we want to use virtual output 1 and virtual output 3, the value to be written to the mask is (1 + 4) = 5.
I.430 Exp OutBySer en (Enabling of Expansion Outputs via serial line)Bitwise mask parameter for expansion virtual digital output.The state of each one of the bits in this maskdetermines if the corresponding digital output terminal of the regulation board is controlled by the drive function(programmed by I.150 ... I.152) or by the expansion virtual digital output.The value which must be assigned to themask is the equivalent decimal of the binary code defined by the state of each switch, as described forparameter I.420 (Bit 0, Bit1and Bit 2).
I.440 An inp by ser en (Enabling of analog inputs via serial line)Bitwise mask parameter for virtual analog input. The state of each one of the bits in this mask determines if thecorresponding function of the drive has to be associated with the virtual analogical input or with the analogicalinput of the terminal board. The value which must be assigned to the mask is the equivalent decimal of thebinary code defined by the state of each switch with respect to:
Mask: = 1 Bit 0 = 1 Virtual input 1 enabling= 2 Bit 1 = 1 Virtual input 2 enabling= 4 Bit 2 = 1 Virtual input 3 enabling= 8 Bit 3 = 1 Virtual input 4 enabling
I.450 An out by ser en (Enabling of Analog outputs via serial line)Bitwise mask parameter for virtual analog output. The status of each bit of this mask determines whether thecorresponding analog output terminal of the regulation board is controlled by the drive function (programmed byI.300, I.310, I.350) or by the virtual analog output. The value which must be assigned to the mask is theequivalent decimal of the binary code defined by the state of each switch, according to the following:
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 129
Mask: = 1 Bit 0 = 1 Virtual analog output 1 enabling= 2 Bit 1 = 1 Virtual analog output 2 enabling= 16 Bit 4 = 1 Virtual expansion analog output 1 enabling
Code Name Selection Default MIN MAX Unit Variation IPA
I.400 Inp by serial en 0 0 255 145
I.410 Exp in by ser en 0 0 15 146
I.420 Out by serial en 0 0 15 147
I.430 Exp OutBySer en 0 0 3 148
I.440 Ab In An da ser 0 0 255 196
I.450 An out by ser en 0 0 255 149
Encoder Configuration
If the optional card EXP-ENC-AGY is mounted, it is possible to read the signals from a digital encoder and use thedetected speed as a feedback for closed loop speed control, or as a frequency reference to be tracked by the drive.
AGy can be configured to work with either HTL (+24V) or TTL (5V or 8V) digital encoders having one or two channels, byproperly setting the HW switches on the optional card and the drive parameters. Maximum input frequency on eachchannel is 150kHz. Refer to the EXP-ENC-AGY manual for detailed electrical specifications and encoder wiringprocedures.
I.500 Encoder enable (Encoder enabling)Enabling of the encoder reading.
I.501 Encoder ppr (Encoder pulses per revolution)Setting of the encoder nameplate pulses per revolution.
I.502 Enc channels cfg (Encoder channels configuration)Setting of the encoder type. The drive is able to read either single-channel or double-channel encoders.
I.503 Enc spd mul fact (Encoder speed multiplier factor)Multiplier factor of the encoder pulses. This parameter allows for management of an encoder that is not directlymounted on the motor shaft (E.g. an encoder mounted on the “slow shaft side” of a gearbox).Has no effect on the closed loop speed control (P.010 Type of control = [1] V/f Clsd loop).
I.504 Enc update time (Encoder updating time)Setting of the sampling time of the encoder pulses. The encoder sampling time affects both the measurementaccuracy and the dynamics that can be achieved in closed loop speed control. Higher sampling times yieldbetter accuracy on the single speed measurement (more pulses counted at a given speed), but introduce asampling delay that reduces the dynamics achievable in closed loop speed control.
NOTE! Due to drive logic internal scaling, the encoder sampling time must be set so that the number of pulsescounted in the interval defined by I.504 never exceeds 32767.
The following formulas relate the number of encoder pulses read by the drive to the actual motor frequency:
The following formulas are for the calculation of the encoder shaft frequency.
F [Hz] = N xmot puls
I.501 [ppr] x T [s] x I.503 [factor]c
x1
Ec
P.041 [polepairs]
N =puls
I.501[ppr] x T [s] x I.503 [factor]c x Ec
P.041 [polepairs]F [Hz] xmot
Motor electrical frequency, expressed in Hz, and motor mechanical speed, expressed in revolutions per minute,
130 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
are related as follows:
n [rpm] =F [rpm] xmot 60[s]
P.041 [polepair] ; F [Hz] =mot
n [rpm] x P.041 [polepairs]
60[s]
Where:F
motMotor electrical frequency detected by the encoder.
n Motor mechanical speed.Tc Encoder sampling time, defined by the parameter I.504.
Npuls Number of encoder pulses counted by the drive in the interval
CT
(displayed as d.300)
Ec Factor due to the encoder type: Ec = 1 if I.502 = [0] One channelEc = 4 if I.502 = [1] Two channel
I.505 Enc supply (Encoder power supply)Setting of the power supply level for the encoder. This parameter determines the voltage level at the power supplyterminals of the EXP-ENC-AGY. Therefore, it is important when using TTL encoders, to select 5V or 8V range.Selection between TTL or HTL is performed by setting the switches on the EXP-ENC-AGY, as explained in themanual of the optional card.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.500 Encoder enable [0] Disable 0 0 1 150
[1] Enable
I.501 Encoder ppr 1024 0 9999 151
I.502 Enc channels cfg [0] One Channel 1 0 1 152
[1] Two Channels
I.503 Enc spd mul fact 1 0.01 99.99 0.01 153
I.504 Enc update time [0] 1ms 0 0 5 sec 0.1 154
[1] 4ms
[2] 16ms
[3] 0.25s
[4] 1s
[5] 5s
I.505 Enc supply [0] 5.2V 0 0 3 181
[1] 5.6V
[2] 8.3V
[3] 8.7V
Serial ConfigurationThe AGy provides as standard an RS485 serial line.
For the connection of the serial line, a 9-pin SUB-D connector, named JP7 or an AMP connector named JP15 (seechapter 5.4 Serial Interface), are available on the regulation card.
The parameters and variables can be written and read through the serial line.
It is also possible to give commands to the drive through serial line, by setting the Cmd source sel (P.000) as follows:
P.000 = 2 Terminal or Virtual
P.000 = 3 Serial
Further information is reported in the chapter PARAMETER, section Commands .
I.600 Serial link cfg (Serial link configuration)Selection of the serial line protocol.Several protocols are available, as shown in the selection list of I.600 at the end of the paragraph.DEFAULT VALUE = 4 (Modbus protocol)
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 131
I.601 Serial link bps (Serial link bit per second)It defines the Baud rate (bit per second) of the serial communication.Possible selections are shown on the table at the end of the paragraph.
I.602 Device addressAddress at which the drive can be accessed if it is networked via the RS485 interface.The range of the selectable addresses is between 0 and 99.As reported in the chapter 5.4 (Serial Line), it is possible to perform a Multidrop configuration with a maximum of32 devices.
I.603 Ser answer delay (Serial link answer delay)Minimum delay setting between the reception of the last byte and the beginning of the corresponding answer.The delay will help avoid conflicts on the serial line, when the RS485 interface is not preset for an automatic Tx/Rx communication.The Ser answer delay (I.603) parameter is specific for the standard serial line RS485.
E.g.: if in the master the communication delay Tx/Rx has a maximum of 20 ms, the setting of Ser answer delay(I.603) parameter will have to be higher than 20ms: 22ms.
I.604 Serial timeout (Serial link timeout)Adjust the maximum time permitted after the reception of the two consecutive frames.If this time elapsed from last activity exceeds the value written in I.604, the drive will behave as programmed byI.605.Setting I.604 to zero will disable the timeout check.
NOTE! Even if the timeout control function is enabled at the drive power-on, the detection of "St" alarm istemporarily non active.
The detection of the alarm will be automatically activated after the first restore of the communicationbetween master and slave.
I.605 En timeout alm (Enabling serial link timeout alarm)Setting of the behaviour for Serial time out alarm.
I.605 = 0 Signalling of the alarm on a digital output (programmed to this purpose)I.605 = 1 Drive in alarm and signalling on a digital output (programmed to this purpose)
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.600 Serial link cfg [0] FoxLink 7E1 4 0 5 155
[1] FoxLink 701
[2] FoxLink 7N2
[3] FoxLink 8N1
[4] ModBus 8N1
[5] JBus 8N1
I.601 Serial link bps [0] 600 baud 4 0 6 156
[1] 1200 baud
[2] 2400 baud
[3] 4800 baud
[4] 9600 baud
[5] 19200 baud
[6] 38400 baud
I.602 Device address 1 0 99 1 157
I.603 Ser answer delay 1 0 250 msec 1 158
I.604 Serial timeout 0 0 25 sec 0,1 159
I.605 En timeout alm [0] Disable 0 0 1 160
[1] Enable
132 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Options Configuration
I.700 Option 1 type[0] Board Off None[1] Board master Reserved[2] IO Board EXP-D6-A1R1-AGy (Optionals I/O card, SIEI code: S524L)[3] Board free Reserved[4] SBI Board SBI-PDP-AGy (Scheda Profibus-DP, SIEI code: S5H28)
I.701 Option 2 type[0] Board Off None[1] Board master Reserved[2] IO Board EXP-D6-A1R1-AGy (Optionals I/O card, SIEI code: S524L)[3] Board free Reserved[4] SBI Board SBI-PDP-AGy (Scheda Profibus-DP, SIEI code: S5H28)
Set up achieved:I.700 Option 1 type = [2] IO BoardI.701 Option 2 type = [4] SBI Board
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.700 Option 1 type [0] Board Off Reserved 0 0 4 161
[1] Board master Reserved
[2] Scheda IO EXP-D6-A1R1-AGy
[3] Board free Reserved
[4] Scheda SBI SBI-PDP-AGy
I.701 Option 2 type [0] Board Off Reserved 0 0 4 162
[1] Board master Reserved
[2] Scheda IO EXP-D6-A1R1-AGy
[3] Board free Reserved
[4] Scheda SBI SBI-PDP-AGy
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 133
SBI ConfigurationIn this menu it is possible to perform the configuration of the SBI card.
Detailed information about the filedbus interfacing, is reported in the specific instruction manuals of the SBI cards.
I.750 SBI AddressSetting of the different addresses of the slaves connected to the bus.
I.751 CAN baudrateCAN Open or DeviceNet baudrate.
I.752 SBI Profibus ModeDefinition of the data exchange structure, between the SBI card of the drive and the Profibus master.
5 different configurations are available: PP0-0 ... PP0-4
PP0-0 User defined structurePP0-1ÖPP0-4 Structures in accordance with Profidrive profile
I.753 SBI CAN ModeSelection of the fieldbus protocol for:I.753 = 0 OFFI.753 = 1 CANOpenI.753 = 2 DeviceNet
I.754 Bus Flt Holdoff (Bus fault hold off from profibus)A communication drop with the fieldbus master, is detected by the SBI card.This parameter allows the setting of a delay for the intervention of the BUS FAULT alarm.
If the communication is restored within this time, the drive will continue working. If this time is elapsed and thecommunication is still missing, an alarm will occur stopping the drive.
If the communication is re-active in the time sets with this parameter, the drive will fault to an alarm storing the"bF" code.
During this stage, the information data (received and sent) is frozen at the status prior to the communicationdrop.At the restoring of the transmission, the first data sent and received will be the one previously frozen.
I.760 SBI to Drv W 0 (SBI to Drive Word 0)
I.761 SBI to Drv W 1 (SBI to Drive Word 1)
I.762 SBI to Drv W 2 (SBI to Drive Word 2)
I.763 SBI to Drv W 3 (SBI to Drive Word 3)
I.764 SBI to Drv W 4 (SBI to Drive Word 4)
I.765 SBI to Drv W 5 (SBI to Drive Word 5)
I.770 Drv to SBI W 0 (Drive to SBI Word 0)
134 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
I.771 Drv to SBI W 1 (Drive to SBI Word 1)
I.772 Drv to SBI W 2 (Drive to SBI Word 2)
I.773 Drv to SBI W 3 (Drive to SBI Word 3)
I.774 Drv to SBI W 4 (Drive to SBI Word 4)
I.775 Drv to SBI W 5 (Drive to SBI Word 5)
Sbi to Drive Wx = Word exchanged from Sbi to DriveDrive to Sbi Wx = Word exchanged from Drive to Sbi
The structure of the data exchange is formed by 6 words.In parameters I.760 ... I.775 must be inserted in the IPA code of the parameter which is to be read or written.
E.g.I.760=311 written parameter F100 Frequency ref 0.I.770=0 read parameter d000 Output frequency
Code Name Selection Default MIN MAX Unit Variation IPA
I.750 SBI address 3 0 255 163
I.751 CAN baudrate [0] 10 Kbit/s 5 0 6 164
[1] 20 Kbit/s
[2] 50 Kbit/s
[3] 125 Kbit/s
[4] 250 Kbit/s
[5] 500 Kbit/s
[6] 1000 Kbit/s
I.752 SBI Profibus mod [0] Custom 2 0 4 165
[1] PPO1
[2] PPO2
[3] PPO3
[4] PPO4
I.753 SBI CAN mode [0] OFF 0 0 2 166
[1] CAN Open
[2] DeviceNet
I.754 Bus Flt Holdoff 0.0 0.1 60 sec 0.1 179
I.760 SBI to Drv W 0 0 0 1999 167
I.761 SBI to Drv W 1 0 0 1999 168
I.762 SBI to Drv W 2 0 0 1999 169
I.763 SBI to Drv W 3 0 0 1999 170
I.764 SBI to Drv W 4 0 0 1999 171
I.765 SBI to Drv W 5 0 0 1999 172
I.770 Drv to SBI W 0 1 0 1999 173
I.771 Drv to SBI W 1 2 0 1999 174
I.772 Drv to SBI W 2 3 0 1999 175
I.773 Drv to SBI W 3 4 0 1999 176
I.774 Drv to SBI W 4 5 0 1999 177
I.775 Drv to SBI W 5 6 0 1999 178
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 135
7.5 Menu F - FREQ & RAMPS
The diagram below, describes the logic for the "Reference selection".
NU
LL
NU
LL
NU
LL
NU
LL
MLT
SP
EED
MLT
SP
EED
MLT
SP
EED
MLT
SP
EED
AN
INP
1
AN
INP
1
AN
INP
1
AN
INP
1
MO
TOR
PO
T
MO
TOR
PO
T
MO
TOR
PO
T
MO
TOR
PO
T
AN
INP
2
AN
INP
2
AN
INP
2
AN
INP
2
AN
INP
3
AN
INP
3
AN
INP
3
AN
INP
3
F.10
0
F.10
0
F.10
1
F.10
3
F.11
5
F.10
2
F.10
1
ENC
OD
ER
ENC
OD
ER
ENC
OD
ER
ENC
OD
ER
0
0 0
0
04
4 4
41
1 1
1
15
5 5
52
2 2
2
26
6 6
63
3 3
3
3 15
7
7 7
7
C T R L
AC
C
UP
DO
WN
RES
ET
DEC
+
+
F.05
0
F.05
1
Ref
eren
ce
F.06
0
F.06
1
Dig input = Multi freq sel
PR
OFI
DR
IVE
8
PR
OFI
DR
IVE
PR
OFI
DR
IVE
PR
OFI
DR
IVE
8
88
Mul
tiFr
eq.1
Cha
nnel
Mul
tiFr
eq.2
Cha
nnel
Ref
.1C
hann
el
Ref
.2C
hann
el
Dig input = Multi freq sel
Dig input = Multi freq sel
Dig input = Multi freq sel
1.0
AN
INP
1
AN
INP
2
0 1 2 3A
NIN
P3
F.08
0
+F.
020
-F.0
20
Figure 7.5.1: Reference Selection
Motorpotentiometer
F.000 Motorpot ref (Motorpotentiometer reference)When this parameter is shown, the UP and DOWN keys are activated to increase or decrease the frequency value.Pressing the UP and DOWN Keys will increase or decrease the motor speed respectively until the keys arereleased.The maximum value settable is defined by Max ref freq (F.020).
NOTE! A RUN command is always necessary, in order to START the motor.
136 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
The Motorpotentiometer reference can also be changed via digital inputs, programmed asMotorpot up and Motorpot down (see par. 7.4, I.000).It is possible to reset the Motorpotentiometer via a digital input programmed as Reset Motorpot.The Motorpotentiometer is reset if the motor is not in “Run” (see par. 7.4, I.000).
F.010 Mp acc/dec time (Motorpotentiometer Acceleration / Deceleration time)It sets the acceleration and deceleration ramp time (in seconds), for the Motorpotentiometer function.
F.011 Motorpot offset (Motorpotentiometer offset)It is the minimum value allowed for the Motorpotentiometer, when configured as unipolar (see F.012). The settingof F.011 will have no effect if the Motorpotentiometer is configured as bipolar.
F.012 Mp output mode (Motorpotentiometer output mode)Variation range of the frequency reference from Motorpotentiometer (unipolar or bipolar).In either setting the HW Reverse command is active (when enabled).
F.013 Mp auto save (Motorpotentiometer auto save)When this function is enabled, the Motorpot reference is continuously saved into non-volatile memory. At power on,the reference will start from the last saved value.When this function is disabled, the Motorpot reference is always zero after power-on.
NOTE! Saving drive parameters by command C.000 (or S.901) will not save the Motorpot ref value.
If F.014 is set = [1] Follow ramp, Motorpot reference is always reset to zero, after power on, regardless of thesetting of F.013 .
F.014 MpRef at stop (Stop mode of Motorpotentiometer function)Behavior of the Motorpotentiometer reference after a STOP command.
F.014 = 0 Motorpotentiometer reference remains fixed to its current value.F.014 = 1 Motorpotentiometer reference ramps down to zero.
When a STOP command is given, Motorpotentiometer reference follows the deceleration rampin use.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.000 Motorpot ref 0 0 F.020 Hz 0.01 300
F.010 Mp acc/dec time 10 0.1 999.9 sec 0.1 301
F.011 Motorpot offset 0 0 F.020 Hz 0.1 302
F.012 Mp output mode [0] Unipolar 0 0 1 303
[1] Bipolar
F.013 Mp auto save [0] Disable 1 0 1 304
[1] Enable
F.014 MpRef at stop [0] Last value 0 0 1 351
[1] Follow ramp
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 137
Reference Limits
F.020 Max ref freq (Maximum reference frequency)Defines the maximum value (absolute value) allowed for the frequency reference.This parameter applies to the sum of the two references available on the drive (Reference 1 and Reference 2).
F.021 Min ref freq (Mimimum reference frequency)It defines the minimum frequency value, under which any regulation with analog or digital references has noeffect.The START of the motor will be carried out (with the ramp delay) at this frequency value also with null reference.As described in the following figure, this behaviour is correlated also to the setting of Min output freq (P.081).
F out Max output freq (P.080)
Max ref freq (F.020)
Min ref freq (F.021)
Set frequency
Min output freq (P.081)(A)
(B)
Figure 7.5.2: Min and Max Reference Frequency
Drive behaviour around minimum values
P.081 settings in A condition
• Giving the RUN command, the motor will reach the frequency set by P.081 (A) without following the setting of
acceleration ramp time.
• The reference action on the frequency curve, will have effect starting from the setting value of P.081 parameter.
P.081 settings in B condition
• Giving the RUN command, the motor will reach the frequency set by P.081 (B) without following the setting of
acceleration ramp time.• References below F.021 will be adjusted to the value of F.021. The variation of P.081 to F.021 is carried out in
the adjusted acceleration time.
The Max output freq (P.080) and the Min output freq (P.081) are expressed as percentage of the values of Maxref freq (F.020).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.020 Max ref freq (****) 25 500 Hz 0.1 305
F.021 Min ref freq 0 0 F.020 Hz 0.1 306
(****) parameter value depending on drive type.
138 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Reference Sources
F.050 Ref 1 Channel (Reference 1 channel)
F.051 Ref 2 Channel (Reference 2 channel)As shown in figure 7.5.1, the source of each of the two frequency referencies can be independently selected.Available selections are reported in the table at the end of this paragraph. The effective frequency reference forthe drive will always be the algebric sum of the two channels.
F.060 Mlt Frq Channel 1 (Multi frequency channel 1)
F.061 Mlt Frq Channel 2 (Multi frequency channel 2)These parameters allow selection of the source of the First and Second frequency reference of the Multispeedfunction (See figure 7.5.1).Available selections are reported in the table at the end of this paragraph.
In the example reported below, it is shown how to switch the source of the frequency reference, between AnalogInput 1 and Motorpotentiometer.
1) set: F.050 - Ref 1 channel = [4] Multispeed2) set: F.060 - MltFrq channel 1 = [1] Analog input 13) set: F.061 - MltFrq channel 2 = [5] Motorpotentiometer4) configure one of the digital input (eg. Dig Inp 1) as follows:
I.000 - Dig input 1 cfg = [7] Freq sel 1 (Binary selection Multispeed function)
The result of the above settings is:a) when Dig input 1 is OFF, the Analog Input 1 is used as main referenceb) when Dig input 1 is ON, the Motorpotentiometer is used as main reference
NOTE! When Dig input 1 is ON, in order to use Motorpot on the keypad, it is necessary to enter the editingmode of F.000 parameter.
F.080 FreqRef fac src (Frequency reference multiplier source)Select the multiplier source of the frequency reference. If set to 1, 2 or 3, the frequency reference resulting by thesum of the two channels, is multiplied by the analog input value (positive only), according to the following formula:
An Inp [%]
FREF,OUT
= FREF,IN
x ___________
50 [%]
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.050 Ref 1 channel [0] Null 3 0 8 307
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Freq ref x (setting through S.203 or F.100)
[4] Multispeed (setting through F.100…F.116)
[5] Motorpotent (setting through F.000…F013)
[6] Analog inp 3 (setting through I.220…I.224)
[7] Encoder (setting through I.500…I.505)
[8] Profidrive Reference from Profibus
F.051 Ref 2 channel [0] Null 0 0 8 308
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Freq ref x (setting through F.101)
[4] Multispeed (setting through F.100…F.116)
[5] Motorpotent (setting through F.000…F013)
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 139
[6] Analog inp 3 (setting through I.220…I.224)
[7] Encoder (setting through I.500…I.505)
[8] Profidrive Reference by Profibus
F.060 MltFrq channel 1 As for F.050, Ref 1 channel 3 0 8 309
F.061 MltFrq channel 2 As for F.051, Ref 2 channel 3 0 8 310
F.080 FreqRef fac src [0] Null 0 0 2 142
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Analog inp 3 (setting through I.220…I.224)
Multispeed Function
F.100 Frequency Ref 0 (Multi frequency channel 1)
F. ...
F.115 Frequency Ref 15 (Multi frequency channel 15)It is possible to select up to 16 frequencies, whose value can be set by these parameters.The selection of these frequencies is performed through the binary setting of digital inputs programmed as Freq sel.The following table describes the basis sequence of the Multispeed selection:
Active Dig ref frequency Freq sel 1 Freq sel 2 Freq sel 3 Freq sel 4
F.100 (Freq Ref 0) 0 0 0 0
F.101 (Freq Ref 1) 1 0 0 0
F.102 (Freq Ref 2) 0 1 0 0
F.103 (Freq Ref 3) 1 1 0 0
F.104 (Freq Ref 4) 0 0 1 0
F.105 (Freq Ref 5) 1 0 1 0
F.106 (Freq Ref 6) 0 1 1 0
F.107 (Freq Ref 7) 1 1 1 0
F.108 (Freq Ref 8) 0 0 0 1
F.109 (Freq Ref 9) 1 0 0 1
F.110 (Freq Ref 10) 0 1 0 1
F.111 (Freq Ref 11) 1 1 0 1
F.112 (Freq Ref 12) 0 0 1 1
F.113 (Freq Ref 13) 1 0 1 1
F.114 (Freq Ref 14) 0 1 1 1
F.115 (Freq Ref 15) 1 1 1 1avy4210
DEFAULT SETTINGS: I.000 - Dig Input 1 cfg (terminal 22) = 7 programmed as Freq sel 1I.001 - Dig Input 1 cfg (terminal 23) = 8 programmed as Freq sel 2
NOTE! “Freq sel 3” and “Freq sel 4” are two functios that can be associated to any of the drive digital inputs.However, in the factory settings they are not associated to any of the terminals on the regulationboard.
140 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
The following figure shows the setting of a 8 Multispeed control.
Freq
Freq ref 0
Freq ref 1
Freq ref 2
Freq ref 3
Freq ref 4
Freq ref 5
Freq ref 6
Freq ref 7t
Freq sel 1
Freq sel 2
Freq sel 3
CMD_RUN
Selectable through“MltFreq Channel 1” (F.060)“MltFreq Channel 2“ (F.061)
Figure 7.5.3: Multispeed Frequencies
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.100 Frequency ref 0 0 -F.020 F.020 Hz 0.1 311
F.101 Frequency ref 1 0 -F.020 F.020 Hz 0.1 312
F.102 Frequency ref 2 0 -F.020 F.020 Hz 0.1 313
F.103 Frequency ref 3 0 -F.020 F.020 Hz 0.1 314
F.104 Frequency ref 4 0 -F.020 F.020 Hz 0.1 315
F.105 Frequency ref 5 0 -F.020 F.020 Hz 0.1 316
F.106 Frequency ref 6 0 -F.020 F.020 Hz 0.1 317
F.107 Frequency ref 7 0 -F.020 F.020 Hz 0.1 318
F.108 Frequency ref 8 0 -F.020 F.020 Hz 0.1 319
F.109 Frequency ref 9 0 -F.020 F.020 Hz 0.1 320
F.110 Frequency ref 10 0 -F.020 F.020 Hz 0.1 321
F.111 Frequency ref 11 0 -F.020 F.020 Hz 0.1 322
F.112 Frequency ref 12 0 -F.020 F.020 Hz 0.1 323
F.113 Frequency ref 13 0 -F.020 F.020 Hz 0.1 324
F.114 Frequency ref 14 0 -F.020 F.020 Hz 0.1 325
F.115 Frequency ref 15 0 -F.020 F.020 Hz 0.1 326
F.116 Jog frequencyIt is the frequency reference for the JOG speed.Jog command is given through a digital input programmed as "Jog", see par. 7.4. Jog command has lowerpriority than Run command. Therefore, if both commands are active, a normal Run will be executed.
The setting of the JOG reference value, can be either positive or negative.Hardware Reverse command (code 2 of digital input) can be used to reverse the motor rotation even during Jog.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.116 Jog frequency 1 -F.020 F.020 Hz 0.1 327
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 141
Ramp ConfigurationDuring normal drive operation, a ramp generator is used to ramp the drive output frequency up or down to a programmedsetpoint.
It is possible to temporarily freeze the ramp generator output, by using a digital input programmed as "Ramp enabled"(DI_Ramp Enable = 0), see 7.4 paragraph, I.000.
It is also possible to force to zero the ramp generator input, programming a digital input as "Zero Ref", see 7.4 paragraph,I.000.
When "DI_ZeroRef=1", motor will stop following the standard drive ramp time; the drive will remain enabled until a STOPcommand is given.
Zero Ref
DI_Ramp Enable
Ramp Output(Motor speed)
Figure 7.5.4: Ramp sequences
Ramp GeneratorDI Zero Ref
0
1
Multi-Ramp
Frequency Reference(set-point)
DI Ramp Enable
0
1
Z-1
Accel time Decel time
DI Ramp Sel 0 DI Ramp Sel 1
CMD_FastStop
CMD_JOG
Figure 7.5.5: Block diagram of ramp generation
F.200 Ramps resolutionIt defines the range and the accuracy of ramp time settings.
F.201 Acc time 1 (Acceleration time 1)
F.202 Dec time 1 (Deceleration time 1)
F.203 Acc time 2 (Acceleration time 2)
F.204 Dec time 2 (Deceleration time 2)
142 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
F.205 Acc time 3 (Acceleration time 3)
F.206 Dec time 3 / FS (Deceleration time 3)
F.207 Acc time 4 (Acceleration time 4)
F.208 Dec time 4 (Deceleration time 4)Ramp acceleration and deceleration times are used to avoid abrupt changes in the inverter output frequency thatmay cause mechanical shocks, excessive motor current and excessive DC-bus voltage. Acceleration times(F.201, F.203, F.205, F.207) are expressed as the time that is needed to ramp up the frequency from 0 tomaximum value specified by Max ref freq (F.020). Conversely, deceleration times (F.202, F.204, F.206, F.208)are expressed as time needed to ramp down the frequency from the maximum value specified by Max ref freq(F.020) to zero.Each of the 4 available ramp sets can be selected by using one or two digital inputs programmed as Rampsel (see par. 7.4, I.000) .The following table describes the ramp selection process:
Active Ramp time Ramp sel 1 Ramp sel 2
F.201 (Acc time 1)
F.202 (Dec time 1)
F.203 (Acc time 2)
F.204 (Dec time 2)
F.205 (Acc time 3)
F.206 (Dec time 3)
F.207 (Acc time 4)
F.208 (Dec time 4)avy4220
0 0
1 0
0 1
1 1
NOTE! When the JOG function is activated, Acc time 4 (F.207) and Dec time 4 (F.208) are automatically selected.
When the "FAST STOP" is activated (through digital input command, see par. 7.4, I.000), the function isexecuted with the DEC TIME 3.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.200 Ramp resolution [0] 0.01s From 0.01s to 99.99s 1 0 2 328
[1] 0.1s From 0.1s to 999.99s
[2] 1s From 1s to 9999s
F.201 Acc time 1 5 0.1(***) 999.9(***) sec 0.1 (***) 329
F.202 Dec time 1 5 0.1(***) 999.9(***) sec 0.1 (***) 330
F.203 Acc time 2 5 0.1(***) 999.9(***) sec 0.1 (***) 331
F.204 Dec time 2 5 0.1(***) 999.9(***) sec 0.1 (***) 332
F.205 Acc time 3 5 0.1(***) 999.9(***) sec 0.1 (***) 333
F.206 Dec time 3 / FS 5 0.1(***) 999.9(***) sec 0.1 (***) 334
F.207 Acc time 4 / Jog 5 0.1(***) 999.9(***) sec 0.1 (***) 335
F.208 Dec time 4 / Jog 5 0.1(***) 999.9(***) sec 0.1 (***) 336
(***) value depends on the setting of F.200 parameter.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 143
F.250 Ramp S-shapeThe S-shaped ramp can be used to obtain a smooth behaviour of the system at the beginning and at the end ofthe acceleration and deceleration.The ramp time, intended as the time needed for accelerating from zero to the maximum frequency F.020, is givenby the sum of the linear ramp time in use and the S-shape time F.250.
F.250 F.250 F.250 F.250
f
t
ACC TIME DEC TIME
Figure 7.5.6: Ramp S-shape
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.250 Ramp S-shape 0 0 10 sec 0.1 337
F.260 Ramp extens src (Ramp extension source)Any of the Analog Inputs can be used to extend the programmed ramp timeThis extension will change linearly according to the value applied on the Analog Input.The programmed ramp times are multiplied by a factor ranging from 1.0, when the Analog Input is less than equalto 10%, to 10.0, when the Analog Input is 100%.
The parameter select the source from where this function is provided and controlled.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.260 Ramp extens src [0] Null 0 0 3 338
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Analog inp 3 (setting through I.220…I.224)
Jump Frequencies
F.270 Jump amplitude
F.271 Jump frequency1
F.272 Jump frequency2In a system composed by motor and drive, at certain frequencies values, it is possible to meet the generation ofnoisy vibrations, caused by mechanical resonances.Through the parameters F.271 and F.272, it is possible to specify two frequencies that are forbidden for inverteroperation.The parameter F.270 defines the band of the forbidden zone.
144 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
F.272
F.271
Freq Reference In
F.270
F.270
F.27
0
F.270
Freq Reference Out
F.270
F.271, F272
Figure 7.5.7: Jump Frequencies
When the frequency reference is set to a value within the forbidden band, the frequency output assumes thefollowing behavior.
Example:
A) Increasing the reference from values lower than F.271
F.271 = 30Hz (first forbidden frequency threshold)F.270 = 1Hz (forbidden band: 29Hz….31Hz)Setting of frequency reference = 29,5HzFrequency output = 29HzSetting of frequency reference = 30,5HzFrequency output = 29Hz
B) Decreasing the reference from values higher than F.271
F.271 = 30Hz (first forbidden frequency threshold)F.270 = 1Hz (tolerance band: 29Hz….31Hz)
Setting of frequency reference = 30,5HzFrequency output = 31Hz
Setting of frequency reference = 29,5HzFrequency output = 31Hz
The user can set any frequency reference, but if its value is within the forbidden range, the inverter will maintainautomatically the speed out of the limit of the tolerance band.
During the ramp execution the forbidden frequencies have no influence, so the output frequency will be linearlygenerated.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
F.270 Jump amplitude 0 0 100 Hz 0.1 339
F.271 Jump frequency 1 0 0 500 Hz 0.1 340
F.272 Jump frequency 2 0 0 500 Hz 0.1 341
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 145
7.6 Menu P - PARAMETERS
Commands
Figure 7.6.1: Basic Commands Logic Selection
Toin
tern
alde
codi
ficat
ion
ofth
ere
gula
tion
I400 I410Terminals
Dig
Inp
Term
Dig
Inp
Exp
Term
FromSerialLink
Dig
Inp
Vir
tual
Dig
Inp
Exp
Vir
tual
H001H000
KEY
PAD
TER
MIN
AL
TER
MIN
AL
OR
VIR
TUA
L
SER
IAL
CO
NTR
OL
WO
RD
P00
0C
omm
and
Sou
rce
Mask
0 1 2 43
D101 d121 d102 d122
d100 d120
146 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Figure 7.6.2: Main Commands Logic Selection
Dec
odifi
catio
n
Dig
Inp
Dig
Inp
Exp
DIR
UN
/FW
D
DIR
EV
DIJ
OG
MO
TOR
DC
B
PIC
KU
P
ALA
RM
RES
ET
ENA
BLE
_NC
P00
1
RU
N
REV
JOG
ENA
BLE
MO
TOR
DC
B
PIC
KU
P
ALA
RM
RES
ET
ENA
BLE
_NO
FRQ
SEL
1
FRQ
SEL
..
(See
Dig
ital
Inpu
tLis
t)
RU
N
STO
P
R S
0K
EYPA
D
1TE
RM
.
2TE
RM
INA
LO
RV
IRTU
AL
3S
ERIA
L
4R
ESER
VED
0K
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d101 d121 d102 d122
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ARTDriveG Instruction manual Chapter 7 - Parameters Description • 147
P.000 Cmd source sel (Command source selection)It defines the source of the main commands (START and STOP) and auxiliary commands (REVERSE, ENABLE,DC-BRAKE, etc.).
P.000 = 0 START & STOP via keypad, auxliliary commands via digital input terminals.In this configuration, START and STOP commands are given through the keypad buttons.
START button STOP button
In order to start the motor, the Digital Input 7 (terminal 5), factory programmed as RUN, must be asserted.If the Digital input programmed as RUN is not active, the motor will STOP with the deceleration ramp time in use.All auxliliary commands are given via digital input terminals.
P.000 = 1 START & STOP and auxliliary commands via digital input terminals.In this configuration, all drive commands are given through the digital input terminals.By default, The START command i given by asserting the Digital Input 7 (terminal 5), factory set asRUN, while the STOP command is given by de-asserting the same Digital Input.It is possible to use several other configurations for giving START, STOP and REV commands fromdigital input terminals. See chapter PARAMETERS, section Commads, for details.
NOTE! At power on, the motor will not start until a positive transition is seen on the Digital Input programmed asRUN (edge sensitive). See description of parameter P.003 for further details.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
P.000 = 2 START & STOP and auxliliary commands via terminals or virtual digital inputs.In this configuration, any drive command may come either from digital input terminals or from virtualdigital inputs. Virtual digital inputs are used to give commands from serial line or fieldbus. Refer tochapter INTERFACE, section Enabling Virtual I/O, for explanation about the use of virtualcommands.
NOTE! At power on, the motor will not start until a positive transition is seen on the Digital Input programmed asRUN (edge sensitive). See description of parameter P.003 for further details.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
P.000 = 3 START & STOP and auxiliary commands via serial line.All drive commands are given through via serial line or filedbus, by using dedicated commands. Referto chapter HIDDEN, section Commands, for a complete description of the available commands.
NOTE! No interlock from digital input terminals is provided, when using commands from serial line.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
P.000 = 4 START & STOP and auxiliary commands via Profidrive control word.In this configuration, all commands are given through the Profidrive standard control word.The optional ProfiBus SBI card is needed.
NOTE! No interlock from digital input terminals is provided, when using commands from Profidrive.
NOTE! Depressing the STOP key on the keypad will cause an emergency stop of the motor. See description ofparameter P.005 for details.
148 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Local/Remote command through digital inputIt is possible to change the source of the main commands via digital input. In order to do so, one of the digitalinpiuts has to be programmed with the code "[29]Local/Remote".
The following figure shows the selection logic for the source of START and STOP commands:
[1] LocalCommand sourceselector P000
[3] Serial
[1] Terminal
Local/Remote selector(digital input)
To drive command logic
[0] Keypad
[0] Remote
----
When the selector (dedicated digital input) is 0 (Remote), START and STOP commands come from the sourcespecified by parameter P.000.When the selector (dedicated digital input) is 1 (Local), START and STOP commands come from the keypad,regardless of what is set into parameter P.000.The status of the digital selector is read by the drive only when the output of the inverter bridge is disabled. As aresult, it is not possible to switch between local and remote source for main commands while the motor isrunning.
P.001 RUN/REV cmd mode (RUN input configuration)Definition of the RUN and Reverse logic control.
P.001 = 0 Run command and Reverse command.
DI RUN/FWD
DI REV(CMD_REV)
CMD_RUN
Motor Speed
Figure 7.6.3: P.000=0 start sequences
P.001 = 1 Run forward command and Run reverse command.
DI RUN/FWD
DI REV(CMD_REV)
CMD_RUN
Motor Speed
Figure 7.6.4: P.000=1 start sequences
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 149
P.001 = 2 Three-wires controll. Run command, Stop command and Reverse command.
DI RUN/FWD
DI REV(CMD_REV)
CMD_RUN
Motor Speed
DI STOP
Figure 7.6.5: P.000=2 start sequences
P.002 Reversal enableP.002 = 0Motor reverse rotation not enabled..
P.002 = 1Motor reverse rotation enabled.
The function, associated to P.002, will be applied to any kind of REV logical command (digital input, negativereference and serial line).
P.003 SafetyThe parameter defines the RUN (or REVERSE) command behavior at the drive power on:
P.003 = 0 Interlock safety disabled.At the drive power on, the starting of the motor is allowed when the RUN command is already present on terminalstrip.
P.003 = 1 Interlock safety enabled.At the drive power on, the starting of the motor is not allowed when the RUN command is already present onterminal strip (Interlock state).The motor can be started by de-asserting and then re-asserting the RUN command.
By monitoring a digital output programmed as "Ready", it is possible to know whether the drive is ready to startor is in the interlocked condition defined above.
P.004 Stop modeMotor stop control function.
P.004 = 0Giving a Stop command, the motor will decelerate down to 0 Hz, following the ramp in use. As soon as theinverter output frequency reaches 0 Hz, the drive is disabled.
P.004 = 1Giving a Stop command, the drive output will be immediately disabled, and the motor will coast to stop.
NOTE! Regardless of the setting of P.004, the drive output can be disabled at any time by de-asserting a digitalinput programmed with code "[13] Enable NO" or by asserting a digital input programmed as "[14]Enable NC".
150 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
P.005 Stop Key ModeStop key configuration.
RUN/STOPfrom programmedsource
STOP KEY
Motor Speed
Alarm Reset
Alarm Signal
Figure 7.6.6: Stop Key Mode sequences
P.000=0 (default configuration) main commands are coming from keypad. Therefore, the STOP key will cause anormal stop of the motor.
P.000≠0 and P.005 = 0, pressing the STOP key will have no effect.
P.000>0 and P.005 = 1Pressing the Stop key, the motor will execute an emergency stop, following the ramp programmed by F.206.After the speed reaches the value zero, the drive will trip with the dedicated alarm “EMS“. An alarm reset will beneeded to restore drive operations (see paragraph 9.2).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.000 Cmd source sel [0] Keypad 0 0 4 400
[1] Terminals
[2] Virtual
[3] Serial
[4] Control word
P.001 RUN input config [0] Run / Rev 0 0 2 401
[1] Fwd / Rev
[2] 3-Wires
P.002 Reversal enable [0] Disable 1 0 1 402
[1] Enable
P.003 Safety [0] OFF 1 0 1 403
[1] ON
P.004 Stop mode [0] Ramp to stop 0 0 1 493
[1] Coast to stop
P.005 Stop Key Mode [0] Inactive 1 0 1 496
[1] EmcStop&Al
Control Mode
P.010 Control mode (Drive control mode)AGy can operate either in open loop or closed loop speed control mode.Open loop speed control is set as default, and does not require speed feedback. The natural variation in speed ofthe induction machine caused by the load, known as slip, can be compensated for by enabling the slipcompensation function (see description of P.100).Closed loop speed control requires speed measurement from a digital encoder coupled to the motor shaft. Theoptional card EXP-ENC-AGY is needed in order to read the encoder signals. The speed detected by the encoder isfed back to a PI speed controller that regulates the inverter output frequency in order to keep the actual motor speedunder control. See Chapter 7, section “Closed loop speed control”, for a complete description of the speed regulator.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 151
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.010 Control Mode [0] V/f open loop 0 0 1 498
[1] V/f clsd loop
Power Supply
P.020 Mains voltageRated value of the AC input mains line to line voltage [V
rms].
The undervoltage trip function is based on this value (see also chapter PARAMETERS, function Undervoltageconfiguration).
P.021 Mains frequencyRated value of the AC input mains frequency [Hz].
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.020 Mains voltage - 230, 380, 400, 420, 440, 460, 480 (****) 230 575 V 404
(Only for "AGy...-4")
- 500, 575 (Only for "AGy...-5")
P.021 Mains frequency 50 (****) 50 60 Hz 405
60
(****) parameter value depending on drive type.
Motor Data
P.040 Motor rated curr (Motor rated current)Rated current [A
rms] of the motor at rated kilowatt/horsepower and voltage (given on the nameplate, see figure 7.6.7).
In case of control with multiple motors, enter a value equal to the sum of the rated currents of all the motors.Do not perform any self tune.
P.041 Motor pole pairsPole pairs of the motor.Starting from nameplate data, the number of pole pairs is calculated as follows:
P =60 [s] x f [Hz]
nN [rpm]
where: p = motor pole pairsf = rated frequency of the motor (P.062)n
N = rated speed of the motor (see figure 7.6.7).
3 kW
Motor: 3 phase
1420 rpm
Motor & Co.
Type: ABCDE
400 V
IP54
Made in ..............
6.7 A
IEC 34-1 / VDE 0530
Iso Kl F
Nr. 12345-91
S1
50 Hz
Power factor 0.8
S.150 (P.040)
S.152 (P.042)
S.101 (P.062) S.100 (P.061)
I nomRated voltage
Rated power
Rated speed (n )N
2 Hp
Motor: 3 phase
1750 rpm
Motor & Co.
Type: ABCDE
575 V
IP54
Made in ..............
2 A
IEC 34-1 / VDE 0530
Iso Kl F
Nr. 12345-91
S1
60 Hz
Power factor 0.83
S.150 (P.040)
S.152 (P.042)
S.101 (P.062) S.100 (P.061)
I nomRated voltage
Rated power
Rated speed (n )N Efficiency 86.5
Figure 7.6.7: Motor Nameplate (Example: kW rating for 400V motor and Hp rating for 575V motor)
152 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Example: calculation of the pole pairs of a motor having data shown in the above 400V label:
p [polepairs] = = = 2.160 [s] x f [Hz]
n [rpm]N
60 [s] x 50 [Hz]
1420 [rpm]
the value to be set in the parameter P.041 is "2".
P.042 Motor power fact (Motor power factor)Motor power factor in rated conditions (given on the nameplate, see figure 7.6.7).
P.043 Motor stator R (Motor stator Resistance)Ohmic value of the stator resistance of the motor.This value will be automatically updated, after performing the self tune procedure.
P.044 Motor coolingSetting of the type of cooling of the motor connected.
P.045 Motor thermal K (Motor thermal costant)Thermal characteristic of the motor connected.The data is normally provided by the motor manufacturer, as the time needed to reach the maximum temperatureat rated current.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.040 Motor rated curr (*) (*) (*) A 0.1 406
P.041 Motor pole pairs (*) 1 60 407
P.042 Motor power fact (*) 0.01 1 0.01 408
P.043 Motor stator R (*) 0 99.99 ohm 0.01 409
P.044 Motor cooling [0] Natural 0 0 1 410
[1] Forced
P.045 Motor thermal K 30 1 120 min 411
V/F Curve
P.060 V/f shapeSelection of the curve for the V/f characteristic.P.060 = 0 (Custom )The intermediate values of voltage and frequency, are defined by the parameters P.063 and P.064 as well as thelink of the manual Boost on the characteristic.
P.120
P.061
P.062
V
P.063
P.064 F.020F
Figure 7.6.8: Custom V/f shape
P.060 = 1 (Linear )
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 153
The factory setting provides a Linear V/f characteristic, having the middle points fixed to half the values of P.062and P.061.The Boost action on the V/f curve will be executed automatically.
P.061
P.062
V
P.0622
P.120
F(n)F.020
P.0612
Figure 7.6.9: Linear V/f shape
P.060 = 2 (Quadratic )The Quadratic characteristic is useful when a pump or fan has to be controlled (load where the torque isproportional to the speed squared).When this ratio is selected, the middle voltage point is fixed to 0,25% of the Max output voltage, and the middlefrequency point is fixed to 50% of P.062.
P.061
F.020
V
F
(P.061 x 0.25)
P.0622
P.120
P.062
Figure 7.6.10: Quadratic V/f shape
P.061 Max out voltage (Maximum output voltage)Maximum value of the voltage to be applied to the motor (normally set as the nameplate, see figure 7.6.7).
P.062 Base frequencyRated frequency of the motor (given on the nameplate, see figure 7.6.7).It is the frequency at which the inverter output voltage reaches the Max out voltage (P.061).
154 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
P.063 V/f interm volt (V/f intermediate voltage)Intermediate "voltage" value of the V/f characteristic selected.
P.064 V/f interm freq (V/f intermediate frequency)Intermediate "frequency " value of the V/f characteristic selected.
NOTE! When custom V/f shape is selected (P.060 = 0):
P.064 parameter represents the return point of the output voltage, on the linear V/f characteristic (seefigure 7.6.8).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.060 V/f shape [0] Custom 1 0 2 412
[1] Linear
[2] Quadratic
P.061 Max out voltage (**) 50 (**) V 1 413
P.062 Base frequency (**) 25 500 Hz 0.1 414
P.063 V/f interm volt (**) 0 P.061 V 1 415
P.064 V/f interm freq (**) 1 P.062 Hz 0.1 416
Ouput Frequency Limit
P.080 Max output freq (Maximum output frequency)It is the maximum allowed of the output frequency of the drive, expressed as percentage of Max ref freq (F.020).
NOTE! When using slip compensation or PID speed regulation, P.080 should be set to a value higher than100%, in order to allow for frequency regulation also when the frequency reference approaches itsmaximum value, defined by Max ref freq (F.020).
P.081 Min output freq (Minimun output frequency)Minimum value of output frequency, under which no frequency regulation has effect.It is expressed as percentage of Max ref freq (F.020).
The parameter is correlated to the Min ref freq (F.021). See description of parameter F.021 for further details.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.080 Max output freq 110 0 110 % of F.020 1 417
P.081 Min output freq 0.0 0.0 25.0 % of F.020 0.1 418
Slip Compensation
P.100 Slip compensat (Slip compensation)When an induction motor is loaded, the mechanical speed of the shaft varies due to the electrical slip betweenstator and rotor quantities which is responsible for the generation of torque.In order to keep the shaft speed constant, the slip compensation function of the drive can be used.The compensation is performed by varying the inverter output frequency of an amount that is calculated frominverter output current and motor parameters. therefore, in oder to obtain best results, motor nameplate data hasto be properly set, and the correct value of the stator resistance (P.043) has to be either edited or measured byself-tuning (S.901). Tuning of the slip compensation function is performed by editing the parameter P.100.If P.100 = 0.0 (default), the slip compensation assumes the nominal value, calculated from nameplate data.P.100 = 0.0 (value by default), the slip compensation has been deactivated.P.100 =100.0, the slip compensation assumes the nominal value calculated from the motor characteristicsboard.
NOTE! The Slip compensation must be disabled when a multiple motor connection is being used.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 155
P.101 Slip comp filter (Slip compensation filter)It is the response time (in seconds) of the slip compensation function.The lower the setting of this parameter, the quicker will be the response od slip compensation. However, settingtoo low may give rise to undesired oscillations of the speed after sudden load variations.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.100 Slip compensat 0 0 250 % 1 419
P.101 Slip comp filter 0.1 0 10 sec 0.1 420
Boost
P.120 Manual boost [%]The resistive impedance of the stator windings causes a voltage drop within the motor, which result in a reductionof torque in the lower speed range.Compensation for this effect can be made by boosting the output voltage.
F.020
P.120
P.061
P.062
V
F(n)
P.064
Figure 7.6.11: Manual Boost Voltage
The setting is in percentage of the Max out voltage (P.061).
P.121 Boost factor src (Factor extension source of manual Boost)The manual Boost level can be linearly regulated by any of the Analog input of the drive.The regulation of the Boost level will be between 0% (An Inp = 0%) and 100% of the value set in P.120 (An Inp =100%).
This parameter selects the Analog input to be used for boost modulation.
P.122 Auto boost en (Automatic boost enabling)By enabling the automatic boost calculation, the drive will optimize the V/f profile in order to obtain constant fluxlevel inside the motor over the whole operating speed range. This will improve torque availability at low speed,increasing the starting torque of the drive. The drive uses the stator resistance of the motor in use (either set inparameter P.043 or measured by the autotuning procedure C.100) and the current measured at the inverter outputterminals to calculate the necessary voltage boost for the V/f profile.
NOTE! Performance achievable with the automatic voltage boost depends on motor parameters. Therefore, inorder to obtain best performance, motor nameplate data should be set correctly and the stator resistancevalue should be measured by running the autotuning procedure.
NOTE! Automatic boost calculation must be disabled when multiple motors are connected to a single inverter.
In some applications, it can be necessary to overflux the machine in order to obtain even more starting torque. Inthose cases, the manual boost (set by P.120) can be used in conjunction to the automatic boost. The resultingvoltage boost will be the sum of the two contributions.
156 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.120 Manual boost [%] 1 0 25 % of P.061 1 421
P.121 Boost factor src [0] Null 0 0 3 422
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Analog inp 3 (setting through I.220…I.224)
P.122 Auto boost en [0] Disable 0 0 1 423
[1] Enable
Automatic Flux Regulation
P.140 Magn curr gain (Magnetizing current gain)The magnetizing current of an induction motor is approximately equal to the no-load current value at rated voltageand rated frequency.By properly setting the parameter P.140, the magnetizing current of the motor and, as a consequence, the motorflux, is controlled to its nominal value, calculated from nameplate data.The main benefit is a higher torque availability at low speed.An excessive value for the gain P.140 may cause undesired oscillation.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.140 Magn curr gain 0 0 100 % 0.1 424
Anti Oscillation Function
P.160 Osc damping gain (Anti Oscillation damping gain)The parameter (current symmetry) is used to eliminate any oscillation or beat in the motor current resulting fromtolerances or configurations capable of generating oscillations within the Inverter/cable/ motor system.If oscillations arise, it is advised to progressively increase the value of P.160, until the oscillation is damped.Excessive values of P.160 may cause instability.The frequency operation range is around 10Hz…30Hz .
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.160 Osc damping gain 0 0 100 1 425
Closed Loop Speed ControlTight control of the speed of the motor is possible, if a digital encoder is coupled to the shaft. The speed deviationis fed to a PI controller, which outputs the necessary correction for the inverter frequency command, in order tocompensate for the slip caused by the load.Closed loop speed control must be enabled by setting the parameter:P.010 Control Mode = [1] V/f Clsd Loop
NOTE! Closed loop speed control is possible only if the drive is equipped with the optional card EXP-ENC-AGY(see chapter 4.4.2). Parameter related to the encoder configuration (I.501 through I.505) must be properlyset, prior to enable closed loop speed control.
NOTE! In order to obtain good dynamics, it is strongly recommended to use a two-channels digital encoder withat least 512ppr.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 157
P.170
P.171
P.172
P.173
P.174 P.175
Gain Profile
PI Regulator
P.176
Slip limits
P.177
-P.177
-P.176
+
+
+
++
+
+
-
fref
fenc
fout
e
k . e + k dtp l e
kp kl
kp
kl
fenc
fenc
LLim
HLim
1Hz-1Hz
LLim
HLim
Figure 7.6.12: Speed control structure.
Proportional and integral gains can be scheduled as a function of the speed, as described in Fig.7.6.12.
The maximum amount of correction of the PI regulator is defined by the user through parameters P.176 andP.177. If the motor is transferring power to the load (motoring), the inverter frequency cannot exceed the followingvalue:
F.020 [Hz]|fout[Hz] < |fenc[Hz]| + P.176 x ________
100.0
If the motor is draining power from the load (braking), the inverter frequency must satisfy the following:
F.020 [Hz]|f
out[Hz] > |f
enc[Hz]| + P.177 x ________
100.0
If the encoder frequency is within ±1.0Hz, linear interpolation is performed between motoring and braking limits,as described in Fig. 7.6.12.
P.170 SpdPgainL (Speed regulator proportional gain at low speed)Proportional gain of the PI speed regulator, applied when the speed is below the threshold defined by P.174 (seeFig.7.6.12).
P.171 SpdIgainL (Speed regulator integral gain at low speed)Integral gain of the PI speed regulator, applied when the speed is below the threshold defined by P.174 (seeFig.7.6.12).
P.172 SpdPgainH (Speed regulator proportional gain at high speed)Proportional gain of the PI speed regulator, applied when the speed is above the threshold defined by P.175 (seeFig.7.6.12).
P.173 SpdIgainH (Speed regulator integral gain at high speed)Integral gain of the PI speed regulator, applied when the speed is above the threshold defined by P.175 (seeFig.7.6.12).
158 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
P.174 SpdGainThrL (Speed regulator gain scheduling low threshold)
P.175 SpdGainThrH (Speed regulator gain scheduling high threshold)The proportional and integral gains of the PI speed regulator equal P.170 and P.171 respectively, when the speedis below the threshold P.174. The gains equal P.172 and P.173 respectively, when the speed is above thethreshold P.175. If the speed is within the two thresholds, the PI gains are calculated by means of linearinterpolation (see Fig. 7.6.12).
P.176 MaxSlipMotor (Maximum amount of allowed slip during motoring)The parameter defines the maximum amount of compensation allowed while motoring (see Fig. 7.6.12). It isexpressed in percentage of parameter F.020.
P.177 MaxSlipRegen (Maximum amount of allowed slip during regeneration)The parameter defines the maximum amount of compensation (negative) allowed while braking (see Fig. 7.6.12).It is expressed in percentage of parameter F.020.
P.178 SpdPI lim FacSrc (Speed PI limits factor source)Each of the analog inputs can be used to modify the output limits of the speed regulator. The resulting limits willbe zero when the analog input is 0% and will increase with the analog input, assuming the values determined byP.176 and P.177 when the analog input is 100%.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.170 SpdPgainL 20.0 0.0 100.0 % 0.1 501
P.171 SpdIgainL 10.0 0.0 100.0 % 0.1 502
P.172 SpdPgainH 20.0 0.0 100.0 % 0.1 503
P.173 SpdIgainH 10.0 0.0 100.0 % 0.1 504
P.174 SpdGainThrL 0.0 0.0 100.0 % of 0.1 507
F.020
P.175 SpdGainThrH 0.0 0.0 100.0 % of 0.1 508
F.020
P.176 SpdRegHLim 10.0 0.0 100.0 % of 0.1 509
F.020
P.177 SpdRegLLim -10.0 -100.0 0.0 % of 0.1 510
F.020
P.178 SRegLimFkSrc [0] Null 0 0 3 511
[1] Analog inp 1
[2] Analog inp 2
[3] Analog inp 3
SW Current Clamp
P.180 SW clamp enable (Software current clamp enabling)To optimize the performance of the inverter, it is necessary to be able to accelerate and decelerate the motor withthe maximum current that the inverter can supply.The setting of very short ramp times, that would cause the output current to exceed the limits of the drive,activates the "Current Clamp"circuit, preventing the drive from tripping for overcurrent (OC).
It is possible to disable the clamp function by setting this parameter to zero.
P.181 Clamp alm HldOff (Hold off time for the current clamp alarmp)f the drive stays at “Active Clamp” status during the time established for this parameter the “LF Fault Limit" alarmis activated.If the value 25.5 [s] is selected for this parameter the alarms are not activated.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 159
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.180 SW clamp enable [0] Disable (not active) 1 0 1 426
[1] Enable (active)
P.181 Clamp alm HldOff 25.5 0.0 25.5 sec 0.1 512
Current LimitThe drive is provided with a function for an active limitation of the current.
It is possible to select different current limits, during the ramps or at steady state.
Current limitation is achieved by a regulating the inverter output frequency (see P.206 parameter).
P.200 Ramp Currlim Mode (Current limitation mode)P.200 = 0 Function disabled.
P.200 = 1 Enabling of the current limit control during the ramps. Current is limited using an active PIregulation of the inverter output frequency.
P.200 = 2 Enabling of current control by ramp freezing.Current is limited by temporarily freezing the acceleration ramp.During speed acceleration or deceleration, if the current value exceeds the setting of P.201 (Currentlimit during the ramp), the ramp stage will be momentary blocked.As soon as the current returns below the limit, the ramp is restarted with.As a result, the actual ramp time is lengthened by the execution of this control.
P.201 Accel curr lim (Current limit in acceleration ramp)Value of the current limit during acceleration ramp.It is expressed as percentage of the nominal current of the drive (see also parameter d.950, chapter DISPLAY).
P.202 En lim in steady (Enabling limit in steady)P.202 = 0 Function disabled.P.201 = 1 Enabling of the current limit control in steady state.The digital entry programmed with the value "[30] En Lim Steady" conditions the state of the current limit when instationary mode. Digital entry= 0 (deactivated limit), digital input = 1 (activated limit).If the function is not programmed in the digital input, it will be controlled through the P.202 parameter only.
P.202 Digital input = [30] Stationary limit status
0 0 Disabled
0 1 Disabled
1 0 Disabled
1 1 Enabled
P.203 Curr lim steady (Current limit in steady)Value of the current limit in steady state.It is expressed as percentage of the nominal current of the drive (see also parameter d.950, chapter DISPLAY).
P.204 Curr ctrl P-gain (Current control proportional gain)Proportional gain of the current regulator.
• a setting too low could cause a slow regulation response.
• a setting too high could cause oscillations of the system.
160 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
P.205 Curr ctrl I-gain (Current control integral gain)Integral gain of the current regulation.
• a setting too low could cause a slow reaction on the regulation response.
• a setting too high could can cause oscillations of the system.
P.206 Curr ctr feedfwd (Current control feed forward)As described in the figure below, the setting of the feed-forward, will prevent tripping of the drive for overcurrent(OC) during fast acceleration of the load.When the current exceeds the value of Curr lim in ramp, a quick frequency step (percentage of the motor ratedslip), is automatically subtracted from the reference.This function operates only during the ramp time (not in steady state).
P.206
n
t
Ramp ProfileSet
P.201
I
tFigure 7.6.13: Current Limit Control in Ramp
A signalling of the "current limit" condition is available on the digital output as "Current limit".A signalling of the "overcurrent" condition is available on the digital output as "Alarm state".
P.207 Decel curr lim (Current limit in deceleration ramp)Value of the current limit during the deceleration ramp.It is expressed as percentage of the nominal current of the drive (see also parameter d.950, chapter DISPLAY).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.200 Ramp Currlim Mode [0] None 0 0 2 427
[1] PI Limit regulator
[2] On/Off Ramp
P.201 Accel curr lim (*) 20 (*) % of I nom 1 428
P.202 En lim in steady [0] Disable 0 0 1 429
[1] Enable
P.203 Curr lim steady (*) 20 (*) % of I nom 1 430
P.204 Curr ctrl P-gain 10.0 0.1 100.0 % 0.1 431
P.205 Curr ctrl I-gain 30.0 0.0 100.0 % 0.1 432
P.206 Curr ctr feedfwd 0 0 250 % 1 433
P.207 Decel curr lim (*) 20 (*) % of Inom 1 494
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 161
DC Link LimitThe function controls the voltage level of the DC link bus capacitor.
During fast deceleration, if the load has a big inertia, the DC link value can suddenly increase close to the alarmthreshold. In this case, the output frequency is controlled keeping the voltage level within safe values.
Consequently, the deceleration ramp time is automatically extended, in order to achieve the deceleration of the load,avoiding an eventual block for "overvoltage" (OV alarm).
As for the current limiter, the DC-Link controller is PI-based, with the addition of a programmable feed forward term.
P.220 En DC link ctrl (Enabling DC link control)P.220 = 0 Function disabled.P.220 = 1 Enabling of the DC link control by means of PI regulation of the inverter output frequency.P.220 = 2 Enabling of the DC link control by ramp freezing.
During fast deceleration, if the DC link level increases close to the alarm threshold, the ramp stageis momentarily blocked.As soon as the DC link level returns within the internal safety values, the ramp is restarted.As a result, the ramp time is lengthened by the execution of this control.
P.221 DC-lnk ctr Pgain (DC link control proportional gain)Proportional gain of the DC link control regulation.- a setting too low could cause a slow regulation response.- a setting too high could cause oscillations of the system.
P.222 DC-lnk ctr Igain (DC link control integral gain)Integral gain of the DC link control regulation.- a setting too low can cause a slow regulation response.- a setting too high can cause oscillations of the DC link.
P.223 DC-link ctr FF (DC link control feed forward)This is the setting of the feed-forward for the DC bus voltage control function.As the DC link level increases above a safety threshold, a quick frequency step (percentage of the motor slip) isautomatically added to the reference. The voltage level decreases toward its rated value. The system will beready to have effect, when the load generates a DC-link voltage variations to low values near the alarm threshold.
P.223
n
t
Ramp ProfileSet
Safety
V Dclink
t
0V Thr
RATEDDclink
Figure 7.6.14: DC Link Voltage Control
A signaling of the "DC link" status is available on the digital output I.000 ... I.103 as "DC bus limit".
162 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.220 En DC link ctrl [0] None 0 0 2 434
[1] PI Limit regulator
[2] On/Off Ramp
PP.221 DC-lnk ctr Pgain 3.0 0.1 100.0 % 0.1 435
P.222 DC-lnk ctr Igain 100 0.0 100.0 % 0.1 436
P.223 DC-link ctr FF 0 0 250 % 1 437
Over Torque Alarm ConfigurationThe torque of the motor is calculated by the drive, as a function of onverter output current and motor parameters.
The behaviour of the drive in case of detection of an excessive torque can be configured by the following parameters.
P.240 OverTorque modeIt defines the behaviour of the drive in case of overtorque detection.
P.240 = 0 Overtorque signalling during ramps and at steady state. No alarm will be generated.P.240 = 1 Overtorque signalling only at steady state. No alarm will be generated.P.240 = 2 Overtorque alarm and signalling during ramps and at steady state.P.240 = 3 Overtorque alarm and signalling only at steady state.
P.241 OT curr lim thr (Overtorque current limit threshold)Overtorque signalling threshold.It is expressed as percentage of the Motor rated curr (P.040).
P.242 OT level fac src (Overtorque level factor source)The overtorque level can be linearly regulated through an analog reference signal.The regulation of this level will be performed between 0% (Analog input = 0%) and 100% of the percentage valueset by P.241 (Analog input = 100%).
This parameter selects the Analog input that has to be used for overtorque threshold modulation.
P.242 = 0 NullP.242 = 1 Analog Inp 1 (setting through I.200 ... I.204)P.242 = 2 Analog Inp 2 (setting through I.210 ... I.214)P.242 = 3 Analog Inp 3 (setting through I.220 ... I.224)
P.243 OT signal delay (Overtorque signalling delay)Delay time for the alarm signalling.
The overtorque alarm will be displayed with the message "Ot"A signalling of the "overtorque" condition is available on the digital output as "Out trq>thr".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.240 OverTorque mode [0] No Alm,Chk on 0 0 0 3 438
[1] No Alm,Chk ss
[2] Alm always
[3] Alm steady st
P.241 OT curr lim thr 110 20 200 % 1 439
P.242 OT level fac src [0] Null 0 0 3 440
[1] Analog inp 1
[2] Analog inp 2
[3] Analog inp 3
P.243 OT signal delay 0.1 0.1 25 sec 0.1 441
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 163
Motor Overload Configuration
P.260 Motor OL prot en (Motor overload protection enabling)Enabling of the motor thermal protection.The control is performed as an I2t, calculated on the basis of the setting ofMotor rated curr (P.040) and Motor thermal K (P.045).An overload of the motor, will cause the intervention of the alarm "Motor overload".
The parameter d.052 (menu DISPLAY), is the motor overload level.A value of 100% represent the threshold for the alarm.
The alarm will be displayed with the message "OLM"
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.260 Motor OL prot en [0] Disable 1 0 1 444
[1] Enable
BU Configuration
P.280 BU Config (Braking unit configuration)The internal brake unit can be disabled by setting this parameter to zero. This is useful when an external BU isused for controlling the DC-link voltage or when several drives share the same DC-link and only one of them is incharge for DC-link voltage control.Also, thermal protection of the braking resistance can be enabled by proper setting of this parameter. Such aprotection requires proper setting of the parameters related to the braking resistor in use (P.281, P282, P.283). Whenthermal protection is enabled, an overheating of the braking resistor will trip the drive for “Braking resistor overload”.
P.280 = 0 Internal BU is disabled.P.280 = 1 Internal BU is enabled; Thermal protection of braking resistor is disabled.P.280 = 2 Internal BU is enabled; Thermal protection of braking resistor is enabled.
NOTE! The internal brake unit, when enabled, will operate even if the drive is disabled. Internal brake unit will notoperate if any of the drive alarms are active.
P.281 Brake res value (Braking resistor value)Rated Ohmic value of the braking resistance connected in use.
P.282 Brake res power (Braking resistor power)Rated power of the braking resistance connected in use.
P.283 Br res thermal K (Braking resistor thermal costant)Thermal constant of the braking resistance connected in use.This data is expressed in seconds, and it is normally provided by the manufacturer of the device, as the time thatthe resistor takes to reach its nominal working temperature while dissipating its rated power.
For further information about the use of braking resistors and braking devices, refer to chapter 5.8.
The parameter d.053 (menu DISPLAY), is the braking resistor overload level.A value of 100% represent the threshold for the alarm.The alarm will be displayed with the message "OLr".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.280 BU config [0] BU disabled 1 0 2 445
[1] BU en OL dis
[2] BU en OL en
P.281 Brake res value (*) 1 250 ohm 1 446
P.282 Brake res power (*) 0.01 25 kW 0.01 447
P.283 Br res thermal K (*) 1 250 sec 1 448
164 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
DC Brake ConfigurationThe drive provides as a standard a set of parameters for the DC braking management.With this function the drive injects a DC current into the motor windings, producing a braking torque.DC braking can be useful to brake the motor around the zero speed, either at START or at STOP, or to maintainthe motor shaft locked for a short time.It should not be used to obtain an intermediate braking.
The parameters described below, allow to fully configure the DC-brake function.
At every DC braking command, the message "DCB" will appear on the display.
P.300 DC braking levelSetting of the DC current level to be injected on the motor phases.It is a percentage of the Motor rated current (P.040).
P.301 DCB lev fac src (DC Braking level factor source)Each of the Analog inputs can be used to modify the current level used for DC braking.The regulation of the DC braking level will be between 0% (Analog input = 0%) and 100% of the value set byP.300 (Analog input = 100%).
This parameter specifies which Analog input has to be used for DC braking current level modulation.
P.302 DC braking freq (DC Braking frequency)It defines the frequency threshold, at which the DC braking will be activated at STOP.
P.303 DC braking startDefines the DC braking duration in seconds, at START (RUN or Reverse).The motor will be locked until this time is elapsed.
P.304 DC braking stopDefines the DC braking duration, in seconds, at STOP (RUN or Reverse commands released and frequencybelow the threshold defined by P.302).
NOTE! • a DC brake command can be carried out also via digital inputs (see chapter INTERFACE,section Digital inputs). In this case a DC brake will be possible at any speed, no matter if thedrive is in STOP or START condition (digital input as DC brake).
• the injection of direct current remains active until the DC Brake command is removed.
• a momentary disabling of the DC braking function is possible via digital input set as DC brake en,(see par. 7.4, I.000).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.300 DC braking level 0 0 100 % of I nom 1 449
P.301 DCB lev fac src [0] Null 0 0 3 450
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Analog inp 3 (setting through I.220…I.224)
P.302 DC braking freq 0 0 500 Hz 0.1 451
P.303 DC braking start 0 0 60 sec 0.1 452
P.304 DC braking stop 0 0 60 sec 0.1 453
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 165
Autocapture functionThe Autocapture function, allows to engage a motor already running.
Without using this function, the connection of an inverter to a rotating motor could cause, the trip of the inverter forovervoltage or overcurrent, soon after the enable.
When the function is enabled, the inverter frequency output will be forced to match the motor speed, avoiding trips.
Main uses are:
• Restart after an inverter alarm
• Pumps and fans rotated by fluids
• Engage of a motor running directly under the mains
P.320 Autocapture modeP.320 = 0 Function disabled
P.320 = 1 1st RUN OnlyThe engaging of the motor is carried out only once, when the first valid RUN command is given after drive poweron.
P.320 = 2 AlwaysThe engaging of the motor is carried out at every valid RUN command.
NOTE! The function can be enabled also through the digital inputs (see chapter INTERFACE, section Digitalinputs).In this case it will be possible to activate Autocapture at any time the command is applied (regarless ofthe setting of P.320).
P.321 Autocapture Ilim (Autocapture current limit)During the Autocapture procedure, the inverter adjust progressively the voltage and the output frequency so thatthe absorbed current does not overcomes the value set in P.321.For a proper setting, the value of this parameter must be higher than the no-load current of the motor in use(d.950, % of inverter nominal current).
P.322 Demagnetiz time (Autocapture demagnetization time)Delay for the beginning of the Autocapture function.It is the time necessary for the demagnetization of the motor. Setting too short, can cause the tripping of"Overcurrent" alarm.
P.323 Autocap f scan t (Autocapture frequency scanning time)Ramp time for the frequency scanning.The initial frequency is determined by the setting of parameter P.325.
P.324 Autocap V scan t (Autocapture voltage scanning time)Ramp time for the voltage recovering.The output voltage will be gradually increased, in oder not to exceed the current limit set in P.321.
P.325 Autocap spd src (Signal source for the frequency scanning)Source of the starting frequency value for the search of the motor speed.
P.325 = 0 Frequency RefThe starting frequency is set to the actual value of the frequency reference. d.001 = Frequency Ref.
P.325 = 1 Max frequency refThe starting frequency is set to the value defined in the parameter F.020 = Max ref freq.
166 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Such setting is recommended when the motor to be engaged has been previously connected to the AC mains(F.020 = 50 or 60Hz).
P.325 = 2 Last frequency refThe starting frequency is set to the value assumed by Frequency Ref at the moment of the last inverter disable.
P.325 = 3 EncoderThe starting frequency is set to a value corresponding to the speed measured by the encoder fit on the motor.Such setting is recommendedwhen the motor is equipped with an encoder.
Mains supply anddrive start
Mains contactoropening
Motor speed
Drive output frequency
Drive output voltage
Waiting for demagnetiz.P.322
Speed search
Acceleration
P.324
P.323
Figure 7.6.15: Autocapture function
Example for the use of the Autocapture function to engage a motor which has been previously mains-connected.P.325 = 1.
Code Name Selection Default MIN MAX Unit Variation IPA
P.320 Autocapture mode [0] Disable 0 0 2 454
[1] 1st run only
[2] Always
P.321 Autocapture Ilim 120 20 (*) % of I nom 1 456
P.322 Demagnetiz time (*) 0.01 10 sec 0.01 457
P.323 Autocap f scan t 1 0.1 25 sec 0.1 458
P.324 Autocap V scan t 0.2 0.1 25 V 0.1 459
P.325 Autocap spd src [0] Frequency ref 0 0 3 460
[1] Max freq ref
[2] Last freq ref
[3] Encoder
A signalling of the "Autocapture" status is available on the digital output as "Autocapture run" .
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 167
Undervoltage ConfigurationA temporary mains voltage drop is detected by the inverter intermediate circuit (DC link) as a variation of its level below asafety threshold. Such a condition causes the inverter to stop due to an undervoltage alarm (UV).
The safety threshold is set via the Undervoltage thr (P.340) parameter.
Procedures for the Undervoltage control
It is possible to configure the behaviour of the inverter in case of momentary drop of the AC mains voltage, thus avoidingunnecessary trips and improving system availability.
When the undervoltage threshold has been overcome, the inverter can initiate one of the following procedures:
• Autorestart (P.341)
• Coast Through (P.343)
• Emg Stop (P.343)
P.340 Undervoltage thr (Undervoltage alarm threshold)Safety threshold for the detection of the undervoltage alarm (UV).It is possible to move the UV threshold between a minimum value defined by the hardware (P.340 = 0) and amaximum value corresponding to the rated DC-link voltage (P.340 = 100%). In order to increase systemavailability, it is recommended to leave P.340 = 0 (factory setting).
AC main supply Minimum UV threshold Nominal DC-Bus
230Vac 230Vdc 310Vdc
380Vac 380Vdc 537Vdc
400Vac 380Vdc 565Vdc
420Vac 400Vdc 594Vdc
440Vac 400Vdc 622Vdc
460Vac 415Vdc 650Vdc
480Vac 415Vdc 678Vdcagy0160
Example:
Parameter S.000 (P.020) Mains voltage = 400VacUV minimum threshold = 380VdcDC bus rated value = 565Vdc
P.340 = 0% UV threshold = 380Vdc
P340 = 50% UV = 380 + = 472,5Vdc(565 - 380) x 50
100
Or, if the UV threshold has to be = 400Vdc, it is possible to calculate the value to be set in P.340:
P.340 = x 100 11%(400 - 380)
(565 - 380)
AUTORESTARTWhen the DC bus voltage value is lower than the value set in P.340, the inverter output bridge is disabled andmotor coasts to stop.DC-bus voltage is restoredbefore the time set in Max pwrloss time (P.341) elapses and if the drive regulationcard remains active, the "Autorestart" function is started.The inverter behaves as described in the "Autocapture" function, regardless of what is set in P.320, therefore thefollowing parameters have to be programmed:
P.321 Autocapture IlimP.322 Demagnetiz timeP.323 Autocap f scanP.324 Autocap V scan
168 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
The following figure shows the "Autorestart" sequence after a short power dip.
Regulationsupply
Mains supply
Motor speed
Outputfrequency
Outputvoltage
Waiting fordemagnetization
P.322
DC Link precharge
Speed searchP.323, P324
Acceleration
Figure 7.6.16: Autorestart after a power dip
P.341 Max pwrloss time (Maximum time for a power supply loss)The Autorestart procedure is performed within this time if the mains voltage is restored. A longer power supplyloss causes the inverter stop and a following "undervoltage" alarm.In case the regulation card is no longer supplied because of a power dip, the restart with the Autorestartprocedure is not possible.P.341 = 0 (default), Autorestart function disabled.
P.342 UV alarm storage (Storage of the undervoltage alarm)This parameter specifies whether an UV alarm occured while the drive is disabled, has to be stored into the"Alarm list".
P.343 UV Trip mode (Controlled stop due to a power dip)Such function can work properly only if the load has sufficient kinetic energy (loads with high inertia-low frictions).
P.343 = 0 DisableIn case of a power supply loss, the drive stops with an "undervoltage" alarm (UV)
P.343 = 1 Coast ThroughIn case of loss of the mains power supply, the drive will decrease the output frequency, recovering the kineticenergy of the load , trying to maintain the regulation board active as long as possible. If the mains voltage isrestored, the drive will resume its normal operation.
P.343 = 2 Emg StopIn case of a power supply loss, the drive decreases the output frequency trying to stop the motor within apreviously fixed period (F.206).
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 169
COAST THROUGH
The function is enabled programming P.343 = 1.
1> 2> 1) Ref A: 100V 1s2) Ref B: 1V 1s
V setpoint
Main loss Main restoring
P223Ref B
VTH threshold
Ref A
Figure 7.6.17: Coast through function
Ref A = DC Link voltageRef B = motor power supply frequency
Phase description:
a) The procedure for the controlled stop is automatically enabled when the DC link voltage decreases below theV
TH: threshold :
VTH=(√2 x Vmains) x 0,8
(Vmains
depends on the value set in the S.000 parameter)
b) The motor power supply frequency is decreased with a step corresponding to P.223 in order to operate in thegenerating mode and to avoid further decrease of the DC bus voltage.
c) A PI regulator controls the drive output frequency and regulates it in order to bring and keep the DC link voltageat the Vsetpoint value:
V =SETPOINT
( VTH2 x V x 0.9)+mains
2
The regulator setpoint is changed linearly from VTH
to Vsetpoint
The response of the PI regulator can be tuned setting the parameters:P.221 DC-link ctr Pgain = P gain.P.222 DC-link ctr Igain = I gain.
In case the mains voltage is restored during the Coast through procedure, the drive recognizes the situation andthe motor rotation speed is brought back to its starting value.On the contrary, if the mains voltage is not restored, the PI regulator further decreases the drive output frequencytill the motor stops (in this way the DC bus can be kept at the Vsetpoint level). At this point the driveUndervoltage alarm is enabled.The motor restart can be obtained performing the safe-restart procedure with the P.003 parameter.
170 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
EMG STOP (Emergency stop)The function is enabled programming P.343 = 2.
VTH threshold
V setpointP223
1>
2> 1) Ref A: 100V 1s2) Ref B: 1V 1s
Ref A
Ref B
Main loss
Figure 7.6.18: Emergency stop
Ref A = DC Link voltageRef B = motor power supply frequency
Phase description:a) The procedure for the controlled stop is automatically enabled when the DC link voltage decreases below the
VTH
threshold:
VTH
=(√2 x Vmains
) x 0,8
(Vmains
depends on the value set in the S.000 parameter)
b) The motor power supply frequency is decreased with a step corresponding to P.223 in order to operate in thegenerating mode and to avoid further decrease of the DC bus voltage.
c) A PI voltage regulator controls the drive output frequency and regulates it in order to bring and keep the DC linkvoltage at the Vsetpoint value:
V =SETPOINT
2 x V + OVmains TH
2(OV
TH = 800 V
DC )
The regulator setpoint is changed linearly from VTH
to VsetpointThe response of the PI regulator can be tuned setting the parameters:P.221 DC-link ctr Pgain = P gain.P.222 DC-link ctr Igain = I gain.
d) When the voltage setpoint reaches Vsetpoint, the regulator is disabled and the drive performs the Fast Stopramp set with the F.206 parameter.
e) During the Fast Stop ramp, the DC bus voltage can reach values suitable to enable the braking resistanceP.220 = 0.In case the resistance is not connected, it is recommended to set P.220 = 1 in order to avoid a possibleOvervoltage alarm during the stop phase.The P.207 parameter allows the setting of the current limit during the controlled stop phase. In case the motorcurrent tries to overcome the current limit, the Fast Stop ramp speed is decreased in order to keep the currentat the programmed level.If, on the contrary, the programmed braking ramp is too slow, the DC bus voltage could decrease below the V
TH
value. In this condition the PI voltage regulator regains the control of the output frequency till the motor stops.At this point the drive Undervoltage alarm is enabled.
In case the mains voltage is restored during the Emg Stop procedure, the drive continues its procedure till themotor is completely stopped. The motor restart can be obtained performing the safe-restart procedure with the
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 171
P.003 parameter.In case of high-inertia loads, it could be convenient to enable the DC braking function at stop. Such functioncould reduce or eliminate a small residual slip rotation of the motor.
Master - Slave functionIn a configuration with multiple drive/motor, where several motors can be set with different speeds but where theratio between the different speeds has to be constant during the machine stopping phases (for example on acarding textile line), it is possible to use the Master-Slave function.To this purpose, it is required to enable the Emg Stop or Coast Through function only on the Master drive and toprogram an analog output with code 22 Freq ref factor. On the other Slave drives forming the line, no UV TripMode function has to be enabled but an analog input F.080 FreqRef fac src has to be programmed, for exampleF.80 = 2, the output frequency reference is multiplied by the analog input value (only positive).
The analog output of the drive configured as master supplies a reference corresponding to the ratio between theoutput frequency of the Fout drive (controlled by the UV Trip Mode function) and the Fout0 frequency referencebefore enabling the function:
Vout = (Fout / Fout0) x 10V
If the UV Trip Mode function is enabled (P.343 = 1 or P.343 = 2) but not active, the analog output corresponding to10V tends to 0V when the UV Trip Mode function is active.By multiplying the frequency set on the slaves by Vout, it is possible to obtain a coordinated stop.Considering that 10V on the analog input used as FreqRef fac src corresponds to a multiplication by 2 of thebase frequency, the input scale has to be set to 0.5:ex. I.222 = An In 3 gain = 0,5The use of the Master-Slave function can be advantageous when all the drives forming the line are connected to asingle DC bus.
Code Name Selection Default MIN MAX Unit Variation IPA
P.340 Undervoltage thr 0 0 80 % of P.020 1 462
P.341 Max pwrloss time 0 0 25 sec 0.1 463
P.342 UV alarm storage [0] Disable 1 0 1 464
[1] Enable
P.343 UV Trip mode [0] Disabled 0 0 2 491
[1] CoastThrough
[2] Emg Stop
Overvoltage Configuration
P.360 OV prevention (Overvoltage prevention)During fast deceleration or in case of deceleration with high inertia load, it is possible to prevent the drive trip fromovervoltage alarm, by enabling this function.
Performing this control, the drive will act as follows:• detection of the overvoltage level, without storing and displaying the alarm.• disabling the inverter output bridge; the motor will coast to stop and DC-link will decrease toward safe values.• automatic enabling of the Autocapture function, and engaging of the motor at the last frequency value,
detected before the alarm.
For correct operations it is necessary to enter the proper settings of the Autocapture parameters:
P.321 Autocapture IlimP.322 Demagnetiz timeP.323 Autocap f scan tP.324 Autocap V scan t
• normal operation is resumed and the motor will be stopped following the programmed ramp.• if during the stop, the load inertia leads again the DC bus at the limit level, the procedure described above
will be iterated.
172 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
P.223
n
t
Coast to Stop
VDClink
t
0V Thr
RatedDClink
Pickup
Ramp Profile Set
Figure 7.6.19: Overvoltage Prevention
The "overvoltage " alarm will be displayed with the message "OV".A signalling of the "overvoltage" condition is available on the digital output as "Alarm state".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.360 OV prevention [0] Disable 0 0 1 465
[1] Enable
Autoreset ConfigurationThe Autoreset function allows the automatic restoring of the driveoperation, after the detection of some alarms.
It will be active only with an appropriate setting of the parameters described below and after the drive has tripped from oneof the following alarms:
• undervoltage (UV)
• overvoltage (OV)
• overcurrent (OC)
• overcurrent desat (OCH)
• external fault (programmable) (EF)
• serial time out (St)
P.380 Autoreset attmps (Autoreset attempts)Setting of the maximum number of autoreset, after the detection of an alarm. If P.380 is set to 0 the function isdisabled.
P.381 Autoreset clearIf enabled, it sets to zero the counter of the already-performed autoreset attempts, if no alarm condition isdetected within a period of time set in the P.381 Autoreset clear parameter. After the counter zero setting, thenumber of the available restart attempts is set in the P.380 Autoreset attmps parameter. If P.381 Autoresetclear is set with 0, the counter zero setting is not performed.
P.382 Autoreset delayDelay that elapses between the failure detection and the beginning of the autoreset sequence.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 173
P.383 Autores flt rly (Autoreset fault relay)Defines the status of the relays and digital outputs, during the autoreset function, according the following table:
Parameters
P.383 Drive OK Alarm state No alarm state
0 ON OFF ON
1 OFF ON OFFtgy0340
"Relays & Dig Out" programming
NOTE! a normal "Alarm Reset" can be enabled also through the digital inputs (see chapter INTERFACE, sec-tion Digital inputs). The reset command will be executed only if the drive is blocked (no RUN orReverse commands) and the cause of the alarm has been eliminated.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.380 Autoreset attmps 0 0 255 466
P.381 Autoreset clear 10 0 250 min 1 467
P.382 Autoreset delay 5 0.1 50 sec 0.1 468
P.383 Autores flt rly [0] OFF 1 0 1 469
[1] ON
External Fault Configuration
P.400 Ext fault mode (External fault mode)Configuration of the behaviour of the drive after an "External fault alarm".
P.400 = 0 Always signalled - Autoreset not possibleP.400 = 1 Signalling only when applied the RUN command - Autoreset not possibleP.400 = 2 Always signalled - Autoreset possibleP.400 = 3 Signalling only when applied the RUN command - Autoreset possible
The alarm will be displayed with the massage "EF".A signalling of the "external fault" condition is available on the digital output as "Extern fault".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.400 Ext fault mode 0 0 3 470
Phase Loss Detection
P.410 Ph Loss detec en (Phase Loss detection enabling)The enabling of this function allows detection of the missing of any phase of the AC input mains.
P.410 = 0 Disabled Phase loss detection disabled.P.410 = 1 Enabled Phase loss detection enabled.
The alarm will be displayed with the message "PH".A signalling of the "phase loss " condition is available on the digital output as "Alarm state".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.410 Ph Loss detec en [0] Disable 1 0 1 492
[1] Enable
174 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Voltage Reduction ConfigurationIt is possible to minimize the energy consumption af a motor that is running with light load by properly configuring thevoltage reduction function.
P.420 Volt reduc mode (Voltage reduction mode)Defines of the mode of the output voltage reduction.P.420 = 0The output voltage reduction is always applied.P.420 = 1The output voltage reduction is not applied during the ramp, providing full torque availability during accelerationand deceleration.The voltage reduction will be activated only at constant speed (end of ramp).
P.421 V reduction fact (Voltage reduction factor)Level of the output voltage that will be applied on the motor terminals.It is a percentage of the voltage, resulting from the V/F characteristic (see figure 7.6.20).
P.422 V fact mult src (Voltage reduction factor multiply source)The output voltage level reduction, can be linearly regulated through an analog reference signal.Its regulation will be performed in a range between 10% (An Inp = 10%) and 100% of the value set in parameterP.421 (An Inp = 100%).The figure below describes this regulation.
NOTE! The level of voltage reduction, will be applied in accordance to the output voltage value, based on thecharacteristic of the V/F characteristic.
Example:
P.421 = 30%V/f motor characteristic = 380V / 50HzMotor supply voltage = 380V / 50Hz
The inverter output voltage at 50 Hz will be:
380 - = 266V380 x 30
100
P.421
100%(10V, 20mA)
An input
VFact
P.42110
Figure 7.6.20: Voltage reduction factor multiply
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 175
100%
V
tF
t
Ramp Profile
P.421
Figure 7.6.21: Output Voltage Reduction with P.420 = 1
NOTE! the function can be enabled also through the digital inputs (see chapter INTERFACE, section Digitalinputs). In this case it will be possible to enable the Output Voltage reduction at any time the commandis applied.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.420 Volt reduc mode [0] Always 0 0 1 471
[1] Steady state
P.421 V reduction fact 100 10 100 % of P.061 1 472
P.422 V fact mult src [0] Null 0 0 3 473
[1] Analog inp 1 (setting through I.200…I.204)
[2] Analog inp 2 (setting through I.210…I.214)
[3] Analog inp 3 (setting through I.220…I.224)
Frequency Threshold
P.440 Frequency prog 1 (Frequency programmed 1)Set point for the detection of the first frequency threshold.The signalling of the frequency level detection can be programmed on the digital outputs.
P.441 Freq prog 1 hyst (Frequency programmed 1 hysteresis)Defines a tolerance band around the Frequency prog 1 (P.440).
P.442 Frequency prog 2 (Frequency programmed 2)Set point for the detection of the second frequency threshold.The signalling of the frequency level detection can be programmed on the digital outputs.
P.443 Freq prog 2 hyst (Frequency programmed 2 hysteresis)Defines a tolerance band around the Frequency prog 2 (P.442).
176 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
P.441
Output Frequency
Output FrequencyAbsolute Value
Tol. Band +
Tol. Band -
Thr SetP.440
Freq=Thr Set
Freq Thr Set
Freq>Thr Set
Freq<Thr Set
P.4412
P.441
P.4412
Figure 7.6.22: Program Frequency Tresholds (example of P.440 and P.441)
A signalling of the "frequency threshold" status is available on the digital output as "Freq thr 1" and "Freq<thr2".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.440 Frequency prog 1 0 0 50 Hz 0.1 474
P.441 Freq prog 1 hyst 0.5 0 50 Hz 0.1 475
P.442 Frequency prog 2 0 0 50 Hz 0.1 476
P.443 Freq prog 2 hyst 0.5 0 50 Hz 0.1 477
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 177
Steady State SignallingThe signalling of the steady state condition can be configured by the following parameters.
P.460 Const speed tol (Constant speed tollerance)It defines the tolerance band of the speed variation.
P.461 Const speed dly (Constant signalling delay)Delay time for the signalling.
n
P.460 Speed ref
P.461 P.461
Steadystatesignal
Figure 7.6.23: Constant Speed Control
A signalling of the "steady state" condition is available on the digital output as "Steady state".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.460 Const speed tol 0 0 25 Hz 0.1 478
P.461 Const speed dly 0,1 0 25 sec 0.1 479
Heatsink Temperature ThresholdControl and monitoring of the drive heatsink temperature.
P.480 Heatsnk temp lev (Heatsink temperature level)Setting of the temperature threshold in °C.
P.481 Heatsnk temp hys (Heatsink temperature hysteresis)Tolerance band for the signalling of the temperature threshold.The parameter d.050 (menu DISPLAY), is the heatsink temperature level .
A signalling of the "heatsink temperature" status is available on the digital output as "Hs temp thr".
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.480 Heatsnk temp lev 70 10 110 °C 1 480
P.481 Heatsnk temp hys 5 0 10 °C 1 481
178 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
PWM Setting
P.500 Switching freq (Switching frequency)Setting of the modulation frequency of the drive.
P.501 Sw freq reduc en (Switching frequency reduction enabling)When enabled, the PWM carrier frequency is automatically changed, according to the inverter output frequency.This can avoid the inverter overheating at low frequencies. Furthermore, it improves the sinewave output, providinga smoother rotation.
P.502 Min switch freq (Minimum switching frequency)Setting of the minimum switching frequency value.
P.520 Overmod max lev (Overmodulation maximum level)Setting of the overmodulation maximum level.This function increases the output voltage, providing as consequence a higher torque availability.Setting the parameter too high the parameter could increase the distortion of the output voltage and give rise toundesired vibrations of the system.
P.540 Out Vlt auto adj (Output voltage automatic adjustement)The voltage applied to the motor terminal is defined by the parameter Max output voltage (P.061), and it isstrictly correlated to the value of the mains voltage.
This function can make the motor output voltage independent of eventual fluctuation of the mains, through anautomatic adjustment of the first.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.500 Switching freq [0] 1kHz (*) 0 (*) 482
[1] 2kHz
[2] 3kHz
[3] 4kHz
[4] 6kHz
[5] 8kHz
[6] 10kHz
[7] 12kHz
[8] 14kHz
[9] 16kHz
[10] 18kHz
P.501 Sw freq reduc en [0] Disable 0 0 1 483
[1] Enable
P.502 Min switch freq As P.500 (*) 0 P.500 495
P.520 Overmod max lev 0 0 100 % 1 484
P.540 Out Vlt auto adj [0] Disable 1 0 1 485
[1] Enable
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 179
Dead Time CompensationThe "dead time compensation" function allows for compensation of the output voltage distorsion due to IGBT voltage dropand its switching characteristics.
Distorsion of output voltage may cause non uniform, non smooth shaft rotation in open loop control.
It is possible to set a voltage value and the compensation variation, called Gradient, through the following parameters.
P.560 Deadtime cmp lev (Dead time compensation level)Dead time compensation level.
P.561 Deadtime cmp slp (Dead time compensation slope)Compensation gradient value.
Dead time slope
i
v
Dead time level
Voltage cmd to pwrOutput voltage
+
+
Figure 7.6.18: Dead Time Compensation
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.560 Deadtime cmp lev (*) 0 255 486
P.561 Deadtime cmp slp (*) 0 255 487
Display Setting
P.580 Startup displayIt is possible to define the first parameter that will be displayed at every power-on of the drive.The choice can be carried out by setting the corresponding "IPA", reported in the parameters list table, into thisparameter.
P.600 Speed dsply fact (Speed display factor)Costant used to convert frequencies to speeds.The parameters is applied to the variable reported in the chapter DISPLAY, sections Basic and Encoder.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.580 Startup display 1 1 1999 488
P.600 Speed dsply fact 1 0.01 99.99 0.01 489
180 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Protection
P.999 Param prot code (Parameters protection code)Protection against undesired modification of the parameters.
P.999 = 0 Protection disabled- Stopped motor: possibility to write all parameters.- Running motor: some parameters are write-protected (see IPA in bold on main tables)
P.999 = 1 All parameters are write-protected except:- F.000 Motorpot ref, F.100 … F.116, multispeed function parameters- P.999 Param prot code- C.000 Save parameter (only with motor stopped)- C.020 Alarm clear- H.500...H511, serial line commands.
P.999 = 2 All parameters are write-protected except:- P.999 Param prot code- C.000 Save parameter (only with motor stopped)- C.020 Alarm clear- H.500...H511, serial line commands.
P.999 = 3 Protection disabled- Stopped motor: possibility to write all parameters.- Running motor: some parameters are write-protected (see IPA in bold on main tables)Possibility to execute Save parameter also with running motor.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
P.999 Param prot code 0 0 3 490
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 181
7.7 Menu A - APPLICATION
PID Setting
Figure 7.7.1: PID Function Block
Ref
eren
ce
Feed
back
Con
fig.
Con
fig
A.0
01
A.0
02
+ -
Sig
n
A.0
06
Kp
prop
.
Td(
deriv
.)D
.402
PID
erro
r
A.0
56/A
.057
A.0
00
D.4
00P
idre
fere
nce
D.4
01P
idre
fere
nce
D.4
04P
IDou
tput
A.0
50(K
p)A
.051
(Ti)
A.0
52(T
d)
A.0
53(K
p)A
.054
(Ti)
A.0
55(T
d)
Set
gain
1
Set
gain
2
Pid
gain
sel
>A
.58&
<=
A.5
9
>A
.58
<=
A.5
9
A.0
07
Pid
inte
g.in
it
Enab
le
Dis
able
A.0
01
PID
refe
nce
sele
ctor
Nul
l=0
Ana
log
inpu
t1
=1
Ana
log
inpu
t2
=2
Ana
log
inpu
t3
=3
Freq
uenc
yre
f=
4.
Ram
pou
tput
=5
Dig
italr
ef=
6En
code
rfr
eque
ncy
=7
A.0
02P
IDfe
edba
ck
Nul
l=0
Ana
log
inpu
t=1
Ana
log
inpu
t=2
Ana
log
inpu
t=3
Enco
der
freq
.=4
Out
putc
urr
=5
Out
putt
orqu
e=
6O
utpu
tpow
er=
7
PID
Hig
h/lo
wlim
it
D.4
03P
IDin
tegr
alco
mpo
nent
Pid
erro
r><
thr
Pid
erro
r>th
r
Pid
erro
r<th
r
Feed
-for
war
d Dig
itali
nput
/out
put
Dis
play
varia
bles
1 0
PID
Free
ze
Ste
ady
Sta
teA
.004
+ +
1 SK
pTi
PID
free
ze
PID
outp
ut
A.0
00
PID
Enab
leEn
able
182 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
All the parameters concerning the setting of the PID function, are contained in the Application menu.
The AGy drive provides a PID function, engineered on purpose for the following controls:
• nip rolls with dancer or load cell
• pressure regulation for pumps and extruders
• speed loop control with encoder
The use of the PID block as stand-alone is also possible, correlated (or not) to the RUN status of the drive.
PID
V/F
A.001PID refence selectorNull = 0Analog input 1 = 1Analog input 2 = 2Analog input 3 = 3Frequency ref = 4Ramp output = 5Digital ref = 6Encoder frequency = 7
A.001Reference
A.002Feed-back
A.002PID feedbackNull = 0Analog input 1 = 1Analog input 2 = 2Analog input 3 = 3Encoder freq. = 4Output curr = 5Output torque = 6Output power = 7
A.000 = 2(Without feed-forward)
A.000PID modeDisable = 0Freq. sum = 1Freq. direct = 2Volt sum = 3Volt direct = 4Stand alone = 5St-Al always = 6
+
-
Figure 7.7.2: PID Mode as Frequency Sum or Direct (A.000=1, 2)
A.000 PID ModeThis parameter defines the regulation mode of the PID function.
A.000 = 0 Disable The function is disabled.A.000 = 1 Freq.sum The output of the PID regulator is added to the ramp output reference value
(with feed-forward).A.000 = 2 Freq.direct The PID regulator output is directly input to the V/f profile generator. Frequency
ramp output is not used.A.000 = 3 Volt sum The PID regulator output is added to the voltage reference, calculated in
accordance with the setting of the V/F characteristic (with feed-forward).A.000 = 4 Volt direct The PID regulator output is the voltage to be applied to the motor. V/f curve is
not used.A.000 = 5 Stand alone The PID function can be used as generic control. The regulator will be active
only when the drive will be in RUN.A.000 = 6 St-Al always The PID function can be used as generic control. The regulator is not correlated
to the drive status.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 183
PID
A.001PID refence selectorNull = 0Analog input 1 = 1Analog input 2 = 2Analog input 3 = 3Frequency ref = 4Ramp output = 5Digital ref = 6Encoder frequency = 7
A.001Reference
A.002Feed-back
A.002PID feedbackNull = 0Analog input 1 = 1Analog input 2 = 2Analog input 3 = 3Encoder freq. = 4Output curr = 5Output torque = 6Output power = 7
A.000 = 4( whitout feed-forward)
A.000PID modeDisable = 0Freq. sum = 1Freq. direct = 2Volt sum = 3Volt direct = 4Stand alone = 5St-Al always = 6
+
-
V/F
Figure 7.7.3: PID Mode as Voltage Sum or Direct (A.000=3, 4)
A.001 PID reference selectorIt defines the source, from where the PID reference signal is provided and controlled.A.001 = 0 Null NullA.001 = 1 Analog inp 1 PID Reference connected to Analog input 1A.001 = 2 Analog inp 2 PID Reference connected to Analog input 2A.001 = 3 Analog inp 3 PID Reference connected to Analog input 3A.001 = 4 Frequency ref PID Reference connected to Frequency referenceA.001 = 5 Ramp output PID Reference connected to Ramp output signalA.001 = 6 Digital ref PID Reference connected to “PID digital ref”parameterA.001 = 7 Encoder freq PID Reference connected to Encoder frequency
A.002 PID Fbk sel (PID feedback selector)It defines the source, from where the PID feed-back signal is provided and controlled.A.002 = 0 Null NullA.002 = 1 Analog inp 1 PID Feed-back connected to Analog input 1A.002 = 2 Analog inp 2 PID Feed-back connected to Analog input 2A.002 = 3 Analog inp 3 PID Feed-back connected to Analog input 3A.002 = 4 Encoder freq PID Feed-back connected to Encoder frequencyA.002 = 5 Output curr PID Feed-back connected to Output current signalA.002 = 6 Output torque PID Feed-back connected to Output torque signalA.002 = 7 Output power PID Feed-back connected to Output power signal
A.003 PID digital ref (PID digital reference)Setting of the reference for the PID function.It will be active only if PID Ref sel (A.001) is set as “6”
A.004 PID activate modeIt defines if the PID function has to be always enabled or if it has to be active in steady state only.A.004 = 0 Always The PID function is always enabled.A.004 = 1 Steady state The PID function is enabled only in steady state.
184 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
A.005 PID-Encoder Sync (PID encoder syncronism)The function syncronizes the updating time of the PID regulator, with the encoder updating time defined by I.504.A.005 = 0 Disable The function is not enabled. The parameter PID update time (A.008) is active.A.005 =1 Enable The function is enabled. Setting of parameter A.008 has no effect on PID regulation.
PID updating time is defined by I.504.
A.006 PID err sign rev (PID error signal reverse)It allows to invert the polarity of the error signal between the reference and the feed-back (as consequence alsothe regulation effect is modified).
A.007 PID Integ Init en (PID integral initialization enabling)The function allows to initialize the “integral parts” at the RUN command or during the passage from “gains set 1”to “gains set 2”. This avoids sudden variations of the regulator output.When the function is active, the value of the integral component, is initialized to:Iinit = Pid output - ( (Kp x err) + (Kd x Derr) ).
A.008 PID update timeIt defines the updating time of the PID regulator. The value 0.00 means minimum updating time (5ms). Thisparameter has no effect if A.005 =1.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
A.000 PID mode [0] Disable 0 0 6 1200
[1] Freq sum
[2] Freq direct
[3] Volt sum
[4] Volt direct
[5] Stand alone
[6] St-Al always
A.001 PID ref sel [0] Null 0 0 7 1201
[1] Analog inp 1
[2] Analog inp 2
[3] Analog inp 3
[4] Frequency ref
[5] Ramp output Ramp output
[6] Digital ref
[7] Encoder freq
A.002 PID fbk sel [0] Null 0 0 7 1202
[1] Analog inp 1
[2] Analog inp 2
[3] Analog inp 3
[4] Encoder freq
[5] Output curr
[6] Output torque
[7] Output power
A.003 PID digital ref 0 -100 100 % 0,1 1203
A.004 PID activat mode [0] Always 0 0 1 1204
[1] Steady state
A.005 PID-Encoder sync [0] Disable 0 0 1 1205
[1] Enable
A.006 PID err sign rev [0] Disable 0 0 1 1206
[1] Enable
A.007 PIDInteg init en [0] Disable 0 0 1 1207
[1] Enable
A.008 PID update time 0 0 2.5 sec 0,01 1208
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 185
PID Gains
A.050 PID Prop gain 1 (PID proportional gain 1)Proportional gain (set 1).
A.051 PID Int t const1 (PID integral constant 1)Integral action time (set 1).
A.052 PID Deriv gain 1 (PID derivative gain 1)Derivative action time (set 1).
A.053 PID Prop gain 2 (PID proportional gain 2)Proportional gain ( set 2).
A.054 PID Int t const2 (PID derivative gain 2)Integral action time (set 2).
A.055 PID Deriv gain 2 (PID integral constant 2)Derivative action time (set 2).
The enabling of the PID regulator and the selection of two different set of gains, can be carried out viaprogrammable digital inputs, as described below.
Digital input configuration to select gain 1 or gain 2.I.100=21 PID gain sel
Discontinuity of the PID output caused by changing the set of gains, can be avoided by enabling the function:PID Integ. Init en ( A.007)
The PID function enabling, is possible by programming the digital inputs as PID Enable (code 20).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
A.050 PID Prop gain 1 0 0 99.99 0.01 1209
A.051 PID Int tconst 1 99.99 0 99.99 0.01 1210
A.052 PID Deriv gain 1 0 0 99.99 0.01 1211
A.053 PID Prop gain 2 0 0 99.99 0.01 1212
A.054 PID Int tconst 2 99.99 0 99.99 0.01 1213
A.055 PID Deriv gain 2 0 0 99.99 0.01 1214
PID Limits
A.056 PID high limitSetting of the maximum allowed PID output.
A.057 PID low limitSetting of the minimum allowed PID output.
A.058 PID max pos err (PID maximun positive error)Setting of the maximum positive limit of the regulator error. It is expressed as percentage of the full scale value.It defines the threshold for the digital output signalling.
186 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
A.059 PID min pos err (PID minimun positive error)Setting of the maximum negative limit of the regulator error. It is expressed as percentage of the full scale value.It defines the threshold for the digital output signalling.Digital output signalling:
18 PID err>< PIP error is >A.058 &<=A.05919 PID err>thr PID error is >A.05820 PID err<thr PID error is <=A.05921 PID er ><(inh) PID error>A.058 &<=A.059 (*)22 PID er >(inh) PID error is >A.058 (*)23 PID er <(inh) PID error is <=A.059 (*)
(*) The control through the digital output, can become active only when the error returns the first time in thepreset interval.
Variable monitoring in the DISPLAY MENUThe PID variables can be monitored in the following parameters:
d.400 PID reference Reference signald.401 PID feedback Feedback signald.402 PID error Signalling of the error between reference and feedbackd.403 PID integral comp Actual value of the integral componentd.404 PID output Actual value of the PID regulator output
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
A.056 PID high limit 100 -100 100 % 0.1 1215
A.057 PID low limit -100 -100 100 % 0.1 1216
A.058 PID max pos err 5 0.1 100 % 0.1 1217
A.059 PID min neg err 5 0.1 100 % 0.1 1218
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 187
APPLICATION SAMPLE: PRESSURE CONTROL
Use of the PID function for pressure control of pumps and extruder.
The analog signals relative to the set-point and to the pressure-transducer must be sent to the inverter that controls theextruder speed. If needed, also the digital command for the PID enabling has to be configured.
M
Extruder
Speed reference
E
DRIVE
-10V
+10V
Feed-back
Pressuresetting
Pressuretransducer
Set
Feed-fwd
0-20mA / 4-20mA
Figure 7.7.4: PID Pressure Control for Pumps and Extruders
Configuration of the Digital input 1 for the PID regulator enabling.
I.000 = 20 (PID enable)
Configuration of the Ref 1 channel for the the main frequency reference.
F.050 = 1 (Analog input 1 as main SPEEDreference)
Configuration of the PID mode parameter.
A.000 = 1 (PID enabled as "Frequency sum")
Configuration of the PID reference selector parameter for the reference of the PID function.
A.001 = 2 (Analog input 2 as pressure setpoint)
Configuration of the PID fbk selector parameter for the feedback of the PID function.
A.002 = 3 (Analog input 3, only current type 0-20mA / 4-20mA, for the pressure transducer)
• In the DISPLAY menu, verify the correct reading of the PID reference (parameter d.400) and of the PID feedback(parameter d.401).
• Set the PID regulators gain as follow:
A.050 = 2 Proportional part
A.051 = 1 Integral part
A.052 = 0 Derivative part
When it is deemed necessary to limit the correction of PID regulator, use the parameters A.056 and A.057.
Enable the PID function using the digital input 1 and execute a drive save parameters.
188 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Programmable Logic InputsThe programmable area is formed by:
- Three AND logical gates with two inputs:
A.300
A.301
AND 1
A.302
A.303
AND 2
A.304
A.305
AND 3I.070 I.071 I.072
- Three OR logical gates with two inputs:
A.306
A.307
OR 1
A.308
A.309
OR 2
A.310
A.311
OR 3I.073 I.074 I.075
- Four logical NOT gates:
NOT 1
A.312NOT 2
A.313NOT 3
A.314NOT 4
A.315I.076 I.077 I.078 I.079
The inputs of each logical gate may be connected to any digital drive input, or to the output of another logical gate, andeven to other digital variables of the drive, by programming the parameter of the output in question.
Parameter I.100 (chapter 7.1 – List of Parameters), contains the complete list of the signals which may be assigned toany logical gate input.
The output of each one of the gates may be used to give an order, programming the output parameter relative to the orderfrom the appropriate mode.
Example:
The Run command is converted into AND in digital input 7 and digital input 4 .
This result can be obtained by carrying out the following set up procedure:
I.006 Dig input 7 cfg = [0] None
I.003 Dig input 4 cfg = [0] None
I.070 AND 1 out cfg = [1] Run
A.300 AND1 In 1 src = [62] DI 7
A.301 AND1 In 2 src = [59] DI 4
A.300 AND1 In 1 src
A.301 AND1 In 2 srcSet up input block AND1. See the list of parameter selections I.100.
A.302 AND2 In 1 src
A.303 AND2 In 2 srcSet up input block AND2. See the list of parameter selections I.100.
A.304 AND3 In 1 src
A.305 AND3 In 2 srcSet up input block AND3. See the list of parameter selections I.100.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 189
A.306 OR1 In 1 src
A.307 OR1 In 2 srcSet up input block OR1. See the list of parameter selections I.100.
A.308 OR2 In 1 src
A.309 OR2 In 2 srcSet up input block OR2. See the list of parameter selections I.100.
A.310 OR3 In 1 src
A.311 OR3 In 2 srcSet up input block OR3. See the list of parameter selections I.100.
A.312 NOT1 In src
A.313 NOT2 In src
A.314 NOT3 In src
A.315 NOT4 In srcSet up input block NOT x. See the list of parameter selections I.100.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
A.300 AND1 In 1 src 49 0 77 1355
A.301 AND1 In 2 src 49 0 77 1356
A.302 AND2 In 1 src 49 0 77 1357
A.303 AND2 In 2 src 49 0 77 1358
A.304 AND3 In 1 src 49 0 77 1359
A.305 AND3 In 2 src 49 0 77 1360
A.306 OR1 In 1 src 49 0 77 1361
A.307 OR1 In 2 src 49 0 77 1362
A.308 OR2 In 1 src 49 0 77 1363
A.309 OR2 In 2 src 49 0 77 1364
A.310 OR3 In 1 src 49 0 77 1365
A.311 OR3 In 2 src 49 0 77 1366
A.312 NOT1 In src 49 0 77 1367
A.313 NOT2 In src 49 0 77 1368
A.314 NOT3 In src 49 0 77 1369
A.315 NOT4 In src 49 0 77 1370
190 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
7.8 Menu C - COMMANDSAll the parameters of the COMMAND menu need to be executed according to the procedure listed below.
Save parameters command is used as example.
COMMAND C000
Save parameters
E Save parameters
Confirm? NO
ESave parameters
Run
Save parameters
Done
COMMAND C000
Save parameters
Save parameters
Confirm? YES
Basic
C.000 Save parametersEvery modification of parameter value has immediate effect on drive operation, but is not automatically stored inpermanent memoryThe Save parameter command is used to store the set of parameters currently in use in permanent memory.The drive signals the presence of unsaved parameters by blinking the dedicated yellow LED (Prg) on the keypad.When the drive is turned off, all unsaved modifications are lost.
C.001 Recall paramThe function recalls the parameters that were previously stored, replacing the ones currently in use.
C.002 Load DeafultRecall of the factory parameters.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
C.000 Save parameters (1) (1) (1) (2) 800
(2)
C.001 Recall param (1) (1) (1) (2) 801
(2)
C.002 Load default (1) (1) (1) (2) 802
(2)
Alarm Register Reset
C.020 Alarm clearThe function resets completely the Alarm List register (D.800ÖD.803).
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
C.020 Alarm clear (1) (1) (1) (2) 803
(2)
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 191
External Key
C.040 Recall key progRecal of the parameters contained in the optional external key PRG-KEY.The key has to be set in the connector JP10 on the regulation board.
C.041 Save pars to keyStorage of the inverter parameters on the optional external key PRG-KEY.The key has to be set in the connector JP10 on the regulation board.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
C.040 Recall key prog (1) (1) (1) (2) 804
(2)
C.041 Save pars to key (1) (1) (1) (2) 805
(2)
LCD keypad
C.070 Recall kbg prog (Recall parameters from LCD keypad)Recall the set of drive parameters previously stored in the permanent memory on board of the KB-EV-LCD/..keypad.
C.071 Save pars to kbg (Save parameters into LCD keypad)Save the set of drive parameters in use, into the permanent memory on board of the KB-EV-LCD/.. keypad.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
C.070 Recall kbg prog (1) (1) (1) (2) 809
(2)
C.071 Save pars to kbg (1) (1) (1) (2) 810
(2)
Tuning
C.100 Measure stator RIt measures the stator resistance of the motor connected.A correct value of the motor parameters will optimize drive performance in terms of torque availability and speedcontrol, when using Automatic boost (P.401) and Slip compensation (P.450).
Do not perform any tune when a multiple motor connection is being used.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
C.100 Measure stator R (1) (1) (1) (2) 806
(2)
(1) : AGy-4A, AGy-5 = Confirm? NOAGy-4 = off
(2) : AGy-4A, AGy-5 = Confirm? YESAGy-4 = do
192 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
7.9 Menu H - HIDDENThis menu is not available on the keypad. The setting and the reading of the parameters here contained, can beperformed exclusively via serial line or through SBI card.
Virtual I/O Commands
H.000 Virtual digital commandBitwise setting of virtual digital inputs.
For further information in relation to the use of virtual digital inputs, see chapter INTERFACE section EnablingVirtual I/O.
H.001 Exp virtual digital commandBitwise setting of expansion virtual digital inputs.
For further information in relation to the use of virtual digital inputs, see chapter INTERFACE section EnablingVirtual I/O.
H.010 Virtual digital stateBitwise setting of virtual digital outputs.
For further information in relation to the use of virtual digital outputs, see chapter INTERFACE section EnablingVirtual I/O.
H.011 Exp Virtual digital stateBitwise setting of expansion virtual digital outputs.
For further information in relation to the use of virtual digital outputs, see chapter INTERFACE section EnablingVirtual I/O.
H.020 Virtual An Output 1
H.021 Virtual An Output 2Setting of the value of virtual analog outputs.
H.020 and H.021 = 0 analog outputs value = 0VH.020 and H.021 = +32767 analog outputs value = +10VH.020 and H.021 = -32767 analog outputs value = -10V
For further information in relation to the use of virtual analog outputs, see chapter INTERFACE section EnablingVirtual I/O.
H.022 Exp Virtual An Output 1Setting of virtual analog output on the expansion board. See description of parameter H.021.
H.025 Virtual analog input 1
H.026 Virtual analog input 2
H.027 Virtual analog input 3Value adjustment for virtual analog inputs.
For further information in relation to the use of virtual analogical inputs, see chapterof virtual analog inputs, seechapter INTERFACE, section Enabling Virtual I/O.
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 193
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
H.000 0 0 255 1000
H.001 0 0 255 1001
H.010 0 0 255 1002
H.011 0 0 255 1003
H.020 0 -32768 32767 1004
H.021 0 -32768 32767 1005
H.022 0 -32768 32767 1006
H.025 0 -32768 32767 1082
H.026 0 -32768 32767 1083
H.027 0 -32768 32767 1084
Profidrive Parameters
H.030 Profidrive Control wordDrive control word in accordance with the Profidrive profile.
For further information please refer to the instruction manual of the SBI card (Profibus).
H.031 Profidrive Status wordDrive status word in accordance with the Profidrive profile.
For further information, refer to the instruction manual of the SBI card (Profibus).
H.032 Profidrive ReferenceUsing a Profibus SBI card, the speed reference of the drive has to be set through this parameter, in accordancewith the Profidrive profile.
H.032 = 0 Reference = 0HzH.032 = +4000 hex Reference = Max ref freq (F.020)H.032 = -4000 hex Reference = - Max ref freq (F.020)
In order to activate the speed reference from profdrive, it is necessay to program the reference selector F.050 =[8]Prof drive. See chapter FREQ & REF, section Reference suorces, for details.
H.033 Profidrive Actual FrequencyReading of the drive output frequency, in accordance with the Profidrive profile.
In order to activate the speed reference from profdrive, it is necessay to program the reference selector F.050 =[8]Profdrive. See chapter FREQ & REF, section Reference suorces, for details.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
H.030 0 0 65535 1007
H.031 0 0 65535 1008
H.032 0 -16384 16383 1040
H.033 1 -16384 16383 1041
194 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
Drive Status
H.034 Drive StatusThis structure, consisting of 4 bits, allows to monitor the drive status.The meaning of each bit is the following:
Bit 0Drive readyBit 1Alarm stateBit 2Motor runningBit 3Steady state
H.040 ProgressIt is the indication, in percentage, of the progress status of the “Save parameters” and "Measur stator R"commands.A displaying of 100% means that the function has been completed.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
H.034 0 0 65535 1042
H.040 0 0 100 1009
Parameters Reading ExtensionWhen using high value for the conversion factor (P.600), the resulting speed parameters reading may exceed the valuesirepresentable with a 16 bit word (+32767, –32767).
In this case, it is still possible to monitor the variables through the following parameters:
H.050 Drive output frequency, 32 bit
H.052 Drive reference frequency, 32 bit
H.054 Output speed (d.000)*(P.600), 32 bit
H.056 Speed Ref (d.001)*(P.600), 32 bit
H.058 Encoder freq, 32 bit
H.060 Encoder speed (d.000)*(P.600), 32 bit
H.062 Act alarmBitwise reading of active alarms (32 bits). Each bit is associated to a specific alarm, according to table 9.3.1.
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
H.050 0 - 2 31 2 31 -1 1010
H.052 0 - 2 31 2 31 -1 1012
H.054 0 - 2 31 2 31 -1 1014
H.056 0 - 2 31 2 31 -1 1016
H.058 0 - 2 31 2 31 -1 1018
H.060 0 - 2 31 2 31 -1 1044
H.062 0 0 2 32 -1 1060
ARTDriveG Instruction manual Chapter 7 - Parameters Description • 195
Remote I/Os Control
H.100 Remote Digital Inputs (0..15)
H.101 Remote Digital Inputs (16..31)
H.110 Remote Digital Outputs (0..15)
H.111 Remote Digital Outputs (16..31)
H.120 Remote Analog input 1
H.121 Remote Analog input 2
H.130 Remote Analog output 1
H.131 Remote Analog output 2All the parameters are reserved
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
H.100 0 0 65535 1021
H.101 0 0 65535 1022
H.110 0 0 65535 1023
H.111 0 0 65535 1024
H.120 0 -32768 32767 1025
H.121 0 -32768 32767 1026
H.130 0 -32768 32767 1027
H.131 0 -32768 32767 1028
Serial Link CommandsAs reported in the chapter PARAMETERS section Commands, when setting the P.000 =3 (SERIAL), the maincommands are given exclusively via serial line or fieldbus.
A command is activate by writing "1" to the related parameter. Below, a complete list of available commands is reported.
H.500 Hardware Reset
H.501 Alarm Reset
H.502 Coast to stop
H.503 Stop with ramp
H.504 Clockwise Start
H.505 Anti-clockwise Start
H.506 Clockwise Jog
H.507 Anti-clockwise Jog
H.508 Clockwise Flying restart
196 • Chapter 7 - Parameters Description ARTDriveG Instruction manual
H.509 Anti-clockwise Flying restart
H.510 DC Brake
H.511 Reserved
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
H.500 0 0 1 1029
H.501 0 0 1 1030
H.502 0 0 1 1031
H.503 0 0 1 1032
H.504 0 0 1 1033
H.505 0 0 1 1034
H.506 0 0 1 1035
H.507 0 0 1 1036
H.508 0 0 1 1037
H.509 0 0 1 1038
H.510 0 0 1 1039
H.511 0 0 1 1043
ARTDriveG Instruction manual Chapter 8 - Serial Protocol• 197
Chapter 8 - Serial Protocol
8.1 Modbus RTU Protocol for AGy drives
8.1.1 Introduction
In the chapter the Drive parameters are referred to as 16-bit Modbus registers; a 32-bit Drive parameter covers thereforetwo Modbus registers.
See chapter 7 for the following correspondences: parameter index and Modbus register.
8.1.2 The MODBUS Protocol
The MODBUS protocol defines the format and the communication modes between a system controlling “master” and oneor more “slaves” aimed at answering to the master requests. The protocol states how the master and the slaves start andstop their communication, how the messages can be exchanged and how the errors can be detected. A common line canhost one master and 99 slaves; this is a protocol logic limit, the device number can be further limited by the physicalinterface; the present implementation foresees a maximum number of 32 slaves to be line-connected.
A transaction can be started exclusively by the master. A transaction can have a direct demand/response format or abroadcast format. The former is addressed to a single slave, the latter to all the line slaves, which, on their turn, give noresponse. A transaction can have a single demand/single response frame or a single broadcast message/no responseframe.
Some protocol features have not been defined. They are: interface standard, baud rate, parity, stop bit number. Theprotocol allows also to choose between two communication “modes”: ASCII and RTU (Remote Terminal Unit). The RTUmode, which is the most efficient, is implemented in the Drives.
The JBUS protocol is similar to the MODBUS protocol; the only difference is given by the address numberingsystem: in MODBUS the numbering system starts from zero (0000 = 1st address) while in JBUS it starts from one(0001 = 1st address); this variance is maintained throughout the whole system. The following descriptions, if nototherwise stated, refer to both protocols.
8.1.3 Message format
In order to communicate between the two devices, the message has to be contained into a “casing”. The casing leaves thetransmitter via a “port” and it is “brought” along the line to a similar “port” on the receiver. MODBUS states the format of thecasing, which, both for the master and for the slave, contains:
• The slave address for the master stated transaction (the address 0 corresponds to a broadcast message sent to allthe slaves).
• The code of the function (already performed or to be performed).
• The data to be exchanged.
• The error control according to the CRC16 algorithm.
If a slave detects an error in the received message (a format, parity or CRC16 error), the message is invalid and thereforerejected; when a slave detects an error in the message, it does not perform the required action and does not answer to thedemand as if the address does not correspond to an on-line slave.
8.1.3.1 The address
As stated above, the MODBUS transactions always involve the master (which controls the line) and one slave at the time(with the exception of broadcast messages). In order to detect the message receiver, the first sent character is a bytecontaining the numeric address of the selected slave. Each slave owns therefore a different address number for itsidentification. The legal addresses go from 1 to 99, while a master message starting with the address 0 means that this isa “broadcast” message simultaneously addressed to all the slaves (the address 0 can not be allocated to a slave). Broadcastmessages are those messages which do not need a response to perform their function, i.e. the allocations.
8.1.3.2 The function code
The second character of the message states the function to be performed by the master message; the slave responsecontains the same code, thus stating that the function has been performed.
198 • Chapter 8 - Serial Protocol ARTDriveG Instruction manual
An implemented subset of the MODBUS functions contains:
• 01 Read Coil Status (Not used for AGy drives)
• 02 Read Input Status (Not used for AGy drives)
• 03 Read Holding Registers
• 04 Read Input registers
• 05 Force Single Coil (Not used for AGy drives)
• 06 Preset Single register
• 07 Read Status
• 15 Force multiple Coils (Not used for AGy drives)
• 16 Preset Multiple Registers
The 01 and 02 functions, so as the 03 and 04 functions, are similar and interchangeable. See chapter 3 for a complete anddetailed description of the functions.
8.1.3.3 CRC16
The last two characters of the message contain the cyclic redundancy code (Cyclic Redundancy Check) calculated accordingto the CRC16 algorithm. As for the calculation of these two characters, the message (address, function code and datathus rejecting the parity and the start and stop bits) is considered as a single and continuous binary number whose mostsignificative bit (MSB) is transmitted as first. The message is multiplied by x16 (it undergoes a 16-bit shift on the left) andthen it is divided by x16+x15+x2+1; it is stated as a binary number (1100000000000101). The integer quotient is rejected andthe 16-bit remainder (it is initialized with FFFFh in order to avoid a zero made message) is added to the sent message. Theobtained message, when the receiver slave has divided it by the same polynomial (x16+x15+x2+1), must have a zeroremainder if no error occurred (if not the slave calculates the CRC again).
Considering that the data serializing device (UART) transmits first the less significative bit (LSB) instead of the MSB asrequired by the CRC calculation, such calculation is performed by inverting the polynomial. Furthermore, as the MSBpolynomial influences only the quotient and not the remainder, the remainder is deleted by making it equal to1010000000000001.
The step by step procedure for the CRC16 calculation is the following:
1) Load a 16-bit register with FFFFh (the bit value is 1).
2) Perform the exclusive OR of the first character with the highest byte in the register; place the result in the register.
3) Perform a one-bit shift of the register on the right.
4) If the bit outcoming the register right side (flag) is 1, perform the exclusive OR between the 1010000000000001generating polynomial and the register.
5) Repeat the steps 3 and 4 for eight times.
6) Perform the exclusive OR of the following character with the highest byte in the register; place the result in theregister.
7) Repeat the steps from 3 to 6 for all the message characters.
8) The content of the 16-bit register is the CRC redundancy code to be added to the message.
8.1.3.4 Message synchronization
The message synchronization between the transmitter and the receiver is obtained by interposing a pause between themessages, such pause being equal to 3.5 times the character period. If the receiver does not receive for a period equal to4 characters, the message is considered to be over; as a consequence the following received byte is treated as the firstbyte of a new message: an address.
8.1.3.5 Serial line setting
The communication foresees the following settings:
• 1 start bit
• 8 data bits (RTU protocol)
• 1 stop bit
• no parity
The baud rate can be selected among the following values:
ARTDriveG Instruction manual Chapter 8 - Serial Protocol• 199
BaudrateTimeout
byte-byte
1200 33 ms
2400 16 ms
4800 8 ms
9600 4 ms
19200 2 ms
38400 1 msagy0800
8.1.4 Modbus functions for the drive
Here following is a detailed description of the MODBUS functions implemented for the Drive. All the values listed in thetables are hexadecimal.
8.1.4.1 Read Output Registers (03)
This function allows to read the value of 16-bit (word) registers containing Drive parameters. The broadcast mode is notallowed.
Request
Together with the Drive address and the function code (03), the message contains the register starting address(starting Address) and the number of the registers to be read; they are both stated on two bytes. The maximumnumber of registers which can be read is 125. The register numbering system starts from zero (word1 = 0) for theMODBUS and from one (word1 = 1) for the JBUS.
Modbus example:
• Drive address 25 (19hex)
• 3 Registers from 0069 (0045hex
) to 0071 (0047hex
).
ADDR FUNC DATA DATA DATA DATA CRC CRC
start start word# word#
Addr HI Addr LO HI LO HI LO
19 03 00 44 00 03 46 06
Response
Together with the Drive address and the function code (03), the message includes a character containing the databyte number and some other characters containing the data. The registers require two bytes where the first onecontains the most significative section.
Example: Response to the above mentioned request.
ADDR FUNC DATA DATA DATA DATA DATA DATA DATA CRC CRC
Byte word word word word word word
Count 69 HI 69 LO 70 HI 70 LO 71 HI 71 LO HI LO
19 03 06 02 2B 00 00 00 64 AF 7A
NOTE! in case the register selected range includes some reserved or missing registers, the value of theseregisters is set to 0.
The drive parameters must be 16 bits (1 Modbus register), unless explicitly stated (for example, H.050 to 32 bits). In thecase of parameters to 32 bits the reading is carried out using 2 Modbus registers.
The first register will be the lower part, the second, the higher part.
8.1.4.2 Read Input Registers (04)
This function is similar to the previous one.
200 • Chapter 8 - Serial Protocol ARTDriveG Instruction manual
8.1.4.3 Preset Single Register (06)
This function allows to set the value of a single 16-bit register. The broadcast mode is allowed.
Request
Together with the Drive address and the function code (06), the message contains the register address (parameter)on two bytes and the value to be allocated. The numbering system of the register addresses starts from zero (word1= 0) for the MODBUS and from one (word1 = 1) for the JBUS.
Modbus example:
• Drive address 38 (26hex
)
• Register 26 (001Ahex
)
• Value 926 (039Ehex
)
ADDR FUNC DATA DATA DATA DATA CRC CRC
bit# bit# WORD WORD
HI LO HI LO HI LO
26 06 00 19 03 9E DF 82
Response
The response is given by transmitting again the received message after the register has been modified.
Example: Response to the above mentioned request.
ADDR FUNC DATA DATA DATA DATA CRC CRC
bit# bit# WORD WORD
HI LO HI LO HI LO
26 06 00 19 03 9E DF 82
8.1.4.4 Read Status (07)
This function allows to read the status of eight predefined bits with a compact message. The broadcast mode is notallowed.
Request
The message contains only the Drive address and the function code (07).
Modbus example:
• Drive address 25 (19hex
)
ADDR FUNC CRC CRC
HI LO
19 07 4B E2
Response
Together with the Drive address and the function code (07), the message includes a character containing the statusbits.
Example: Response to the above mentioned request.
ADDR FUNC DATA CRC CRC
status
byte HI LO
19 07 6D 63 DA
The bit meaning is the following:
ARTDriveG Instruction manual Chapter 8 - Serial Protocol• 201
Bit number Bit meaning
0 Digital Output 1
1 Digital Output 2
2 Digital Output 3
3 Digital Output 4
4 Run
5 Steady state
6 Drive limit state
7 Not usedagy0801
8.1.4.5 Preset Multiple Registers (16)
This function allows to set the value of a consecutive block made of 16-bit registers. The broadcast mode is allowed.
Request
Together with the Drive address and the function code (16), the message contains the starting address of theregisters to be written (starting Address), the number of registers to be written, the number of bytes containing thedata and the data characters. The register numbering system starts from zero (word1 = 0) for the MODBUS andfrom one (word1 = 1) for the JBUS.
Modbus example:
• Drive address 17 (11hex
)
• Starting Register 35 (0023hex
)
• Number of registers to be written 1 (0001hex
)
• Value 268 (010Chex
)
ADDR FUNC DATA DATA DATA DATA DATA DATA DATA CRC CRC
start start word# word# Byte word word
Addr HI Addr LO HI LO Count 35 HI 35 LO HI LO
11 10 00 22 00 01 02 01 0C 6C 87
Response
Together with the Drive address and the function code (16), the message contains the starting address (startingAddress) and the number of written registers.
Example: Response to the above mentioned request.
ADDR FUNC DATA DATA DATA DATA CRC CRC
start start word# word#
Addr HI Addr LO HI LO HI LO
11 10 00 22 00 01 A3 53
8.1.5 Error management
In MODBUS there are two kinds of errors which are managed in different ways: transmission errors and operating errors.The transmission errors change the format, the parity (if used) or the CRC16 of the message. When the Drive detectssuch errors, it considers the message invalid and gives no response. If the message format is the right one but its functioncan not be performed, the error is an operating one. The Drive answers to this error with a particular message. Thismessage contains the Drive address, the code of the required function, an error code and the CRC. In order to underlinethat the response is aimed at stating the presence of an error, the function code is returned with the most significative bitset with “1”.
202 • Chapter 8 - Serial Protocol ARTDriveG Instruction manual
Modbus example:
• Drive address 10 (0Ahex
)
• Coil 1186 (04A2hex
)
ADDR FUNC DATA DATA DATA DATA CRC CRC
start start bit# bit#
Addr HI Addr LO HI LO HI LO
0A 01 04 A1 00 01 AC 63
Response
The request refers to the content of the Coil 1185 which does not exist in the Drive slave. The slave answers withthe error code “02” (ILLEGAL DATA ADDRESS) and goes back to the function code 81h (129).
Example: Exception to the above mentioned request.
ADDR FUNC DATA CRC CRC
Except.
Code HI LO
0A 81 02 B0 53
8.1.5.1 Exception codes
This protocol implementation foresees only four exception codes:
Code Name Meaning
01 ILLEGAL FUNCTION The received function code does not correspond to a function allowed on the addressed slave.
02 ILLEGAL DATA ADDRESS The address number, which the data field refers to, is not a register allowed on the addressed slave.
03 ILLEGAL DATA VALUE The value to be allocated, which the data field refers to, is not allowed for this register.
07 NAK - NEGATIVE The function can not be performed with the present operating
ACKNOWLEDGEMENT conditions or attempt to write a read-only parameter.
8.1.6 System configuration
The configuration of the serial line can be performed by programming the parameters in the menu INTERFACE, submenuSerial Config. Some parameters are common to all the implemented protocols (Fox Link, Modbus, etc); the menu containsthe following parameters:
Code LCD display [Code] & LCD select. Default MIN MAX Unit Variation IPA
I.600 Serial link cfg [0] FoxLink 7E1 4 0 5 155
[1] FoxLink 701
[2] FoxLink 7N2
[3] FoxLink 8N1
[4] ModBus 8N1
[5] JBus 8N1
I.601 Serial link bps [0] 600 baud 4 0 6 156
[1] 1200 baud
[2] 2400 baud
[3] 4800 baud
[4] 9600 baud
[5] 19200 baud
[6] 38400 baud
I.602 Device address 1 0 99 1 157
I.603 Ser answer delay 1 0 250 msec 1 158
I.604 Serial timeout 0 0 25 sec 0,1 159
I.605 En timeout alm [0] Disable 160
[1] Enable
ARTDriveG Instruction manual Chapter 8 - Serial Protocol• 203
8.2 Proprietary protocol
8.2.1 Introduction
The Fox Link protocol defines the format and the communication mode between a system controlling master and one ormore slaves responding to the master requests. It defines how the master and the slaves start and end the communication,how the messages are exchanged and how the errors are detected.
It is possible to have one master and 32 slave devices connected to the line.
The slave address has to be a number included between 0 and 99.
Only the master can start a transition. A transition can have a request/response format addressed to a single slave or it canhave a Broadcast format, where the message is sent to all the slaves on the line.
With the I.600 "Serial link cfg" and I.601 "Serial link bps" parameters it is possible to specify the number of data bits, parity,number of stop bits, baudrate.
Parameter Code Protocol type Data bits Parity Stop bits
Serial link cfg 0 Foxlink 7E1 7 Even 1
Serial link cfg 1 Foxlink 7O1 7 Odd 1
Serial link cfg 2 Foxlink 7N2 7 None 2
Serial link cfg 3 Foxlink 8N1 8 None 1
Serial link cfg 4 Modbus 8N1 8 None 1
Serial link cfg 5 Jbus 8N1 8 None 1
tab 821
Parameter Code Baudrate
Serial link bps 0 600
Serial link bps 1 1200
Serial link bps 2 2400
Serial link bps 3 4800
Serial link bps 4 9600
Serial link bps 5 19200
Serial link bps 6 38400
tab 822
8.2.2 Message format
All transmitted characters are 7-bit ASCII format.
The parameter values are specified with integer decimal numbers and with units of measure equal to the highest foreseenresolution (if not otherwise stated).
The transmission string has the following format:
<EOT>, <HAD>,<HAD>,<LAD>,<LAD>, <STX>, X,y,y,y,=,n,…,n, <ETX>, <CKS>, <CR>
Start code Slave address Data
start
Data Data
end
Control code
tab823
<EOT> = 04H
<STX> = 02H
<ETX> = 03H
<ACK> = 06H
<NAK> = 15H
<HAD> = most significant digit of inverter address
<LAD> = least significant digit of inverter address.
<CKS> = XOR of characters between <STX> and <ETX> eventually added to 20H if XOR is less than 20H.
<CR> = 0DH end character for each string
X = letter stating the menu containing the transmitted parameter
y,y,y = numeric code representing the transmitted parameter
The numeric code has to be turned into a 3-character string filling the non-significant characters with '0'.
204 • Chapter 8 - Serial Protocol ARTDriveG Instruction manual
Example: the transmitted parameter has a numeric code equal to 1, therefore the 3-character string to betransmitted is "001".
n,…,n = value of the parameter to be read or written..
8.2.3 Address
As mentioned above, the Foxlink transitions always include the master, which controls the line, and one slave at the time(with the exception of the Broadcast messages). In order to identify the message receiver, the bytes 1,2,3,4,5 contain theaddress of the selected slave. Each slave is therefore identified by a single address. The legal addresses are includedbetween 0 and 99. A message sent with a 99 address means that the message is a "broadcast" one, i.e. it is addressed toall slaves simultaneously. The message reception is granted by all mains-connected slaves while the response for theperformed reception is sent only by the drive with address 99, if it is available on the mains. With the I602 "Device address"parameter it is possible to specify the slave address.
8.2.4 Control code
The checksum is calculated performing the XOR of the characters included between <STX> and <ETX>. If the obtained valueis lower than 20H, the 20H value is then added.
8.2.5 Functions
The following table lists the menus and the letter representing the menu which can be reached using the Foxlink protocol.
Display “D” Read
Interface “I” Read/Write
Freq & Ramp “F” Read/Write
Parameter “P” Read/Write
Application “A” Read/Write
Command “C” Write
Hidden “H” Read/Write
Function Msg Master Msg Slave Meaning
<STX>,D,y,y,y,=n,…,n,<ETX>,<CKS>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
tab824
Display
reading...,<STX>,D,y,y,y,<ETX> , …
Function Msg Master Msg Slave Meaning
<STX>,I,y,y,y,=n,…,n,<ETX>,<CKS>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
<ACK>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
tab825
Interface
reading…,<STX>,I,y,y,y,<ETX>,…
Interface
writing…,<STX>,I,y,y,y,=,n,…,n,<ETX>,…
Function Msg Master Msg Slave Meaning
<STX>,F,y,y,y,=n,…,n,<ETX>,<CKS>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
<ACK>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
tab826
Freq & Ramp
writing…,<STX>,F,y,y,y,=,n,…,n,<ETX>,…
Freq & Ramp
reading…,<STX>,F,y,y,y,<ETX>,…
ARTDriveG Instruction manual Chapter 8 - Serial Protocol• 205
Function Msg Master Msg Slave Meaning
<STX>,P,y,y,y,=n,…,n,<ETX>,<CKS>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
<ACK>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
tab827
…,<STX>,P,y,y,y,<ETX>,…
Parameter
writing…,<STX>,P,y,y,y,=,n,…,n,<ETX>,…
Parameter
reading
Function Msg Master Msg Slave Meaning
<STX>,A,y,y,y,=n,…,n,<ETX>,<CKS>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
<ACK>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
tab828
…,<STX>,A,y,y,y,=,n,…,n,<ETX>,…Application
writing
Application
reading…,<STX>,A,y,y,y,<ETX>,…
Function Msg Master Msg Slave Meaning
<ACK>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
tab829
Command
writing
…,<STX>,C,y,y,y,=,n,<ETX>,…
dove n = 1
Function Msg Master Msg Slave Meaning
<STX>,H,y,y,y,=n,…,n,<ETX>,<CKS>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
<ACK>,<CR> Accepted Function
<STX>,E,<ETX>,<CKS>,<CR> Non-Accepted Function
<NAK>,<CR> Wrong Reception
tab830
Hidden
writing
Hidden
reading…,<STX>,H,y,y,y,<ETX>,…
…,<STX>,H,y,y,y,=,n,…,n,<ETX>,…
8.2.6 Msg Slave meaning
The Wrong Reception Message is returned when a communication error occurs (wrong checksum).
The Non-Accepted Message is returned if:
- a read-only parameter is written,
- a non existing parameter is read or written,
- the written value is outside the allowed range,
- a parameter which can be written only with a stopped motor is written when the motor is rotating.
206 • Chapter 8 - Serial Protocol ARTDriveG Instruction manual
NOTES:
ARTDriveG Instruction manual Chapter 9 - Troubleshooting • 207
Chapter 9 - Troubleshooting
9.1 Drive Alarm Condition
The drive keypad will show on the 2nd line of alphanumeric display a blinking message with the code and name of the alarmoccurred.
The figure below shows an example of OV Overvoltage alarm condition during Output frequency (d.000) parameter displaying.
Hz A VPrg Rev Fwd
Prg
Output frequency0V Overvoltage
Alarm message blinking Res
et
Hz A VPrg Rev Fwd
Prg
0U
Alarm code blinking
Red LEDs
blinking
Red LEDs
blinking
Figure 9.1.1: Alarm Displaying for LDC and 7 segments display
Alarm acknowledge
The active alarm can be acknowledged by pressing the Prg button on the keypad. This operation will allow menu navigationand parameter editing while the drive is in alarm state (red LEDs blinking). In order to resume drive operation, an Alarm resetcommand is necessary.
9.2 Alarm Reset
Alarm reset can be performed in three different ways:
- Alarm reset by keypad : pressing simultaneously Up and Down keys; the reset action will take effect whenthe buttons are released.
- Alarm reset by digital input: it can be performed through a programmable digital input programmed as “[5] Alarmreset”, factory set to Digital Input 5 (terminal 7).
. Alarm reset by Autoreset function: it allows an automatic reset of some drive alarms (see table 8.3.1), by the settingsof P.380, P.381, P.382 and P.383 parameters.
The figure below shows how to reset an alarm by keypad.
Output frequency
0V Overvoltage
Output frequency
0.00 Hz
Alarm condition Alarm resetted
Blinking
Figure 9.2.1: Alarm Reset
208 • Chapter 9 - Troubleshooting ARTDriveG Instruction manual
9.3 List of Drive Alarm Events
Table 9.3.1 provides a description of the causes for all the possible alarms.
Table 9.3.1 Alarm Event List
Cod. Name
EF EF Ext Fault It trips when External fault input is active 1 YES 0
OC OC OverCurrent It trips when an Overcurrent value is detected by output current sensor 2 YES 1
OU OV OverVoltageIt trips when the drive DC Bus voltage is higher than the maximun threshold
for the given main voltage setting (see par. 5.8.1)3 YES 2
UU UV UnderVoltageIt trips when the drive DC Bus voltage is lower than the maximun threshold for
the given main voltage setting4 YES 3
OH OH OverTemperatIt trips when the drive heatsink temperature detected by the switch sensor
exceeds its threshold (*)5 NO 4
OLi OLi Drive OL It trips when the drive overload accumulator exceeded the trip threshold 6 NO 5
OLM OLM Motor OL It trips when the drive overload accumulator exceeded the trip threshold 7 NO 6
OLr OLr Brake res OL It trips when the motor overload accumulator exceeded the trip threshold 8 NO 7
Ot Ot Inst OverTrqIt trips when the torque delivered by the motor exceeds the programmed level
for the preset time9 NO 8
PH PH Phase lossIt trips when the supply phase lack: enabled 30 seconds after one of the
supply phases has been disconnected10 NO 9
FU FU Fuse Blown It trips when the drive input fuses are blown 11 NO 10
OCH OCH Desat Alarm IGBT desaturation or instantaneous overcurrent have been detected 12 YES 11
St St Serial TO It trips when the serial link time out exceeds the programmed level 13 YES 12
OP1 OP1 Opt 1 AlmCommunication failure between drive regulation board and option 1 expansion
board14 NO 13
OP2 OP2 Opt 2 AlmCommunication failure between drive regulation board and option 2 expansion
board15 NO 14
bF bF Bus Fault Drive comunication Bus failure 16 NO 15
OHS OHS OverTemperat It trips when the drive heatsink temperature exceeds a safety level. (*) 17 NO 16
SHC SHC Short Circ Short Circuit between output phases or Ground fault 18 NO 17
Ohr Reserved 19 18
Lf LF Limiter fault
It trips when the output current limiter or the DC-Link voltage limiter fail.
The failure can be caused by wrong settings of regulator gains or by the motor
load.
This alarm may be activated although the drive is in “Current Clamp” status for
a time which exceeds the duration programmed with P181.
20 NO 19
PLC PLC Plc fault Reserved 21 NO 20
EMS Key Em Stp faultThe Stop key has been depressed, while main commands source was any but
the keypad and P.005 "Stop key mode" = [1] EmgStop & Al22 NO 21
UHS UHS Under TemperatIt trips when the temperature of the drive heatsink is below a safety level
(typically –5°C).23 NO 22
Bit
H.0
62
H.0
63
ALARM
DESCRIPTION
AU
TO
RE
SE
T
Nu
me
ric
al
co
de
fro
ms
eri
al
(*) OH switch sensor threshold and OHS analog sensor threshold depend on the drive size (75 °C ... 85 °C)
9.4 Kbg fw mismatch
When the alphanumeric display is connected to the drive, a firmware compatibility check is automaticallyperformed. If firmware version of the alphanumeric display does not match with firmware version of the drive,the warning message “Kbg FW mismatch” is issued on the KB-EV-LCD/.. display for few seconds.In this condition, some parameters may not be shown with the associated description string, but only withIdCode. Also, some selection list may not be visualized correctly.By using E@syDrives configurator, it is possible to upgrade the firmware of the alphanumeric display.
ARTDriveG Instruction manual Chapter 10 - EMC Directive, Declarations of EC-Conformity • 209
Chapter 10 - EMC Directive, Declarations of EC-Conformity
EMC DirectiveThe possible Validity Fields of the EMC Directive (89/336) applied to PDS
“CE marking” summarises the presumption of compliance with theEssential Requirements of the EMC Directive, which is formulated in the EC Declaration of Conformity
Clauses numbers [.] refer to European Commission document “Guide to the Application of Directive 89/336/EEC”1997 edition. ISBN 92-828-0762-2
Validity Field
-1-Finished Product/
Complex componentavailable to general public
[Clauses: 3.7, 6.2.1, 6.2.3.1 &6.3.1]
A PDS (or CDM/BDM) of the
Unrestricted Distribution class
-2-Finished Product/
Complex componentonly for professional assemblers
[Clauses: 3.7, 6.2.1, 6.2.3.2 &6.3.2]
A PDS (or CDM/BDM)
of the Restricted Distribution class
sold to be included as part of a
system or installation
-3-Installation[Clause: 6.5]
Several combined items of system,
finished product or other components
brought together at a given place.
May include PDSs (CDM or BDM),
possibly of different classes -
Restricted or Unrestricted
-4-System
[Clause: 6.4]
Ready to use finished item(s). May
include PDSs (CDM or BDM),
possibly of different classes
- Restricted or Unrestricted
DescriptionPlaced on the market as a single commercial unit for distribution and final use.
Free movement based on compliance with the EMC Directive
- EC Declaration of conformity required - CE marking required
- PDS or CDM/BDM should comply with IEC 1800-3/EN 61800-3
The manufacturer of the PDS (or CDM/BDM) is responsible for the EMC behaviour of the PDS
(or CDM/BDM), under specified conditions. EMC measures outside the item are described in an
easy to understand fashion and could actually be implemented by a layman in the field of EMC.
The EMC responsiblity of the assembler of the final product is to follow the manufacturer’s
recommendations and guidelines.
Note: The manufacturer of the PDS (or CDM/BDM) is not responsible for the resulting behaviour of
any system or installation which includes the PDS, see Validity Fields 3 or 4.
Not placed on the marked as a single commercial unit for distribution and final use.
Intended only for professional assemblers who have a level of technical competence to correctly
install.
- No EC Declaration of conformity - No CE marking
- PDS or CDM/BDM should comply with IEC 1800-3/EN 61800-3
The manufacturer of the PDS (or CDM/BDM) is responsible for the provision of installation
guidelines that will assist the manufacturer of the apparatus, system or installation to achieve
compliance.
The resulting EMC behaviour is the responsibility of the manufacturer of the apparatus, system,
or installation, for which its own standards may apply.
Not intended to be placed on the market as a single functional unit (no free movement).
Each system included is subject to the provisions of the EMC Directive.
- No EC Declaration of conformity - No CE marking
- For the PDSs or CDM/BDMs themselves see Validity Fields 1 or 2
- Responsibility of the manufacturer of the PDS may include commissioning
The resulting EMC behaviour is the responsibility of the manufacturer of the installation in co-
operation with the user (e.g. by following an appropriate EMC plan). Essential protection require-
ments of EMC Directive apply regarding the neighbourhood of the installation.
Has a direct function for the final user. Placed on the market for distribution as a single functional
unit, or as units intended to be easily connected together.
- EC Declaration of conformity required - CE marking required for the system
- For the PDSs or CDM/BDMs themselves see Validity Fields 1 or 2
The resulting EMC behaviour, under specified conditions is the responsibility of the manufac-
turer of the system by using a modular or system approach as appropriate.
Note: The manufacturer of the system is not responsible for the resulting behaviour of any
installation which includes the PDS, see Validity Field 3.
Rel
ates
to
PD
S or
CD
M o
r B
DM
dir
ectl
yR
elat
es t
o ap
plic
atio
n of
PD
S or
CD
M o
r B
DM
Examples of application in the different Validity Fields:1 BDM to be used anywhere: (example in domestic premises, or BDM available from commercial distributors), sold without any knowledge of the purchaser or the
application. The manufacture is responsible that sufficient EMC can be achieved even by any unknown customer or layman (snap-in, switch-on).2 CDM/BDM or PDS for general purpose: to be incorporated in a machine or for industrial application This is sold as a subassembly to a professional assembler who
incorporates it in a machine, system or installation. Conditions of use are specified in the manufacturer’s documentation. Exchange of technical data allows optimisationof the EMC solution.. (See restricted distribution definition).
3 Installation: It can consist of different commercial units (PDS, mechanics, process control etc.). The conditions of incorporation for the PDS (CDM or BDM) arespecified at the time of the order, consequently an exchange of technical data between supplier and client is possible. The combination of the various items in theinstallation should be considered in order to ensure EMC. Harmonic compensation is an evident example of this, for both technical and economical reasons. (E.g.rolling mill, paper machine, crane, etc.)
4 System: Ready to use finished item which includes one or more PDSs (or CDMs/BDMs); e.g. household equipment, air conditioners, standard machine tools,standard pumping systems, etc.
210 • Chapter 10 - EMC Directive, Declarations of EC-Conformity ARTDriveG Instruction manual
ARTDriveG Instruction manual Chapter 10 - EMC Directive, Declarations of EC-Conformity • 211
212 • Index Parameters ARTDriveG Instruction manual
MENU A - APPLICATION
A.000 PID Mode ............................................ 182
A.001 PID reference selector ......................... 183
A.002 PID Fbk sel .......................................... 183
A.003 PID digital ref ....................................... 183
A.004 PID activate mode ............................... 183
A.005 PID-Encoder Sync ............................... 184
A.006 PID err sign rev ................................... 184
A.007 PID Integ Init en ................................... 184
A.008 PID update time ................................... 184
A.050 PID Prop gain 1 ................................... 185
A.051 PID Int t const1 ................................... 185
A.052 PID Deriv gain 1 .................................. 185
A.053 PID Prop gain 2 ................................... 185
A.054 PID Int t const2 ................................... 185
A.055 PID Deriv gain 2 .................................. 185
A.056 PID high limit ....................................... 185
A.057 PID low limit ........................................ 185
A.058 PID max pos err .................................. 185
A.059 PID min pos err ................................... 186
A.300 AND1 In 1 src ...................................... 188
A.301 AND1 In 2 src ...................................... 188
A.302 AND2 In 1 src ...................................... 188
A.303 AND2 In 2 src ...................................... 188
A.304 AND3 In 1 src ...................................... 188
A.305 AND3 In 2 src ...................................... 188
A.306 OR1 In 1 src ........................................ 189
A.307 OR1 In 2 src ........................................ 189
A.308 OR2 In 1 src ........................................ 189
A.309 OR2 In 2 src ........................................ 189
A.310 OR3 In 1 src ........................................ 189
A.311 OR3 In 2 src ........................................ 189
A.312 NOT1 In src ......................................... 189
A.313 NOT2 In src ......................................... 189
A.314 NOT3 In src ......................................... 189
A.315 NOT4 In src ......................................... 189
MENU C - COMMANDS
C.000 Save parameters ................................. 190
C.001 Recall param ....................................... 190
C.002 Load Deafult ........................................ 190
C.020 Alarm clear .......................................... 190
C.040 Recall key prog .................................... 191
C.041 Save pars to key .................................. 191
C.070 Recall kbg prog ................................... 191
C.071 Save pars to kbg ................................. 191
C.100 Measure stator R ................................. 191
MENU D- DISPLAY
d.000 Output frequency ................................... 96
d.001 Frequency ref ........................................ 96
d.002 Output current ....................................... 96
d.003 Output voltage ....................................... 96
d.004 DC link voltage ...................................... 96
d.005 Power factor .......................................... 96
d.006 Power [kW] ........................................... 96
d.007 Output speed ......................................... 96
d.008 Speed ref .............................................. 96
d.050 Heatsink temp ....................................... 97
d.051 Drive OL ................................................ 97
d.052 Motor OL ............................................... 98
d.053 Brake res OL ......................................... 98
d.054 Reserved ............................................... 98
d.100 Dig inp status ........................................ 98
d.101 Term inp status ...................................... 98
d.102 Vir dig inp stat ....................................... 98
d.120 Exp dig inp stat ...................................... 99
d.121 Exp term inp .......................................... 99
d.122 Vir exp dig inp ....................................... 99
d.150 Dig out status ........................................ 99
d.151 Term dig out sta .................................... 99
d.152 Vir dig out stat ....................................... 99
d.170 Exp dig out stat ................................... 100
d.171 Exp DrvDigOutSta ................................ 100
d.172 Exp vir dig out ..................................... 100
d.200 An in 1 cnf mon ................................... 100
d.201 An in 1 monitor ................................... 100
d.202 An in 1 term mon ................................ 100
d.210 An in 2 cnf mon ................................... 100
d.211 An in 2 monitor ................................... 101
d.212 An in 2 term mon ................................ 101
d.220 An in 3 cnf mon ................................... 101
d.221 An in 3 monitor ................................... 101
d.222 An in 3 term mon ................................ 101
d.300 EncPulses/Sample ............................... 101
d.301 Encoder freq ........................................ 101
d.302 Encoder speed .................................... 102
d.350 Option 1 state ...................................... 102
d.351 Option 2 state ...................................... 102
d.353 SBI State ............................................. 102
d.354 SBI Baude rate ..................................... 102
d.400 PID reference ...................................... 102
d.401 PID feedback ....................................... 102
d.402 PID error ............................................. 102
d.403 PID integr comp .................................. 103
d.404 PID output ........................................... 103
d.800 1st alarm-latest ................................... 103
d.801 2nd alarm ............................................ 103
d.802 3rd alarm ............................................ 103
d.803 4th alarm ............................................. 103
d.950 Drive rated curr ................................... 103
d.951 Software type ...................................... 103
d.952 Software version ................................. 103
d.953 Power ident code ................................. 103
d.954 Param ident code ................................ 104
d.955 Regul ident code .................................. 104
d.956 Startup id code .................................... 104
d.957 Drive size ............................................ 104
d.958 Drive cfg type ...................................... 104
d.999 Display Test ......................................... 104
MENU F - FREQ & RAMP
F.000 Motorpot ref ....................................... 135
F.010 Mp Acc / Dec time ............................... 136
F.011 Motorpot offset .................................... 136
F.012 Mp output mode .................................. 136
F.013 Mp auto save ...................................... 136
F.014 MpRef at stop ...................................... 136
F.020 Max ref freq ......................................... 137
F.021 Min ref freq ......................................... 137
F.050 Ref 1 Channel ...................................... 138
F.051 Ref 2 Channel ...................................... 138
F.060 Mlt Frq Channel 1 ................................ 138
F.061 Mlt Frq Channel 2 ................................ 138
F.080 FreqRef fac src .................................... 138
F.100 Frequency Ref 0 ................................. 139
F.115 Frequency Ref 15 ............................... 139
F.116 Jog frequency ..................................... 140
F.200 Ramps resolution ................................ 141
F.201 Acc time 1 ........................................... 141
F.202 Dec time 1 .......................................... 141
F.203 Acc time 2 ........................................... 141
F.204 Dec time 2 .......................................... 141
F.205 Acc time 3 ........................................... 142
F.206 Dec time 3 .......................................... 142
F.207 Acc time 4 ........................................... 142
F.208 Dec time 4 .......................................... 142
F.250 Ramp S-shape .................................... 143
F.260 Ramp extens src ................................. 143
F.270 Jump amplitude ................................... 143
F.271 Jump frequency 1 ............................... 143
F.272 Jump frequency2 ................................ 143
MENU H - HIDDEN
H.000 Virtual digital command ....................... 192
H.001 Exp virtual digital command ................. 192
H.010 Virtual digital state ............................... 192
H.011 Exp Virtual digital state ........................ 192
H.020 Virtual An Output 1 .............................. 192
H.021 Virtual An Output 2 .............................. 192
H.022 Exp Virtual An Output 1 ........................ 192
H.025 Virtual analog input 1 ........................... 192
H.026 Virtual analog input 2 ........................... 192
H.027 Virtual analog input 3 ........................... 192
H.030 Profidrive Control word ........................ 193
H.031 Profidrive Status word ......................... 193
H.032 Profidrive Reference ............................ 193
H.033 Profidrive Actual Frequency ................. 193
H.034 Drive Status ......................................... 194
H.040 Progress ............................................. 194
H.050 Drive output frequency, 32 bit .............. 194
H.052 Drive reference frequency, 32 bit ......... 194
H.054 Output speed (d.000)*(P.600), 32 bit ... 194
H.056 Speed Ref (d.001)*(P.600), 32 bit ........ 194
H.058 Encoder freq, 32 bit ............................. 194
H.060 Encoder speed (d.000)*(P.600), 32 bit . 194
H.062 Act alarm ............................................ 194
H.100 Remote Digital Inputs (0..15) ............... 195
H.101 Remote Digital Inputs (16..31) ............. 195
H.110 Remote Digital Outputs (0..15) ............ 195
H.111 Remote Digital Outputs (16..31) .......... 195
H.120 Remote Analog input 1 ........................ 195
H.121 Remote Analog input 2 ........................ 195
H.130 Remote Analog output 1 ...................... 195
H.131 Remote Analog output 2 ...................... 195
H.500 Hardware Reset ................................... 195
H.501 Alarm Rese ......................................... 195
H.502 Coast to stop ....................................... 195
H.503 Stop with ramp .................................... 195
H.504 Clockwise Start ................................... 195
H.505 Anti-clockwise Start ............................ 195
H.506 Clockwise Jog ..................................... 195
H.507 Anti-clockwise Jog .............................. 195
H.508 Clockwise Flying restart ....................... 195
H.509 Anti-clockwise Flying restar t ................ 196
H.510 DC Brake ............................................. 196
H.511 Reserved ............................................. 196
MENU I - INTERFACE
I.000 Dig input 1 cfg ..................................... 111
I.001 Dig input 2 cfg ..................................... 111
I.002 Dig input 3 cfg ..................................... 111
I.003 Dig input 4 cfg ..................................... 111
I.004 Dig input 5 cfg ..................................... 111
I.005 Dig input 6 cfg ..................................... 111
I.006 Dig input 7 cfg ..................................... 111
I.007 Dig input 8 cfg ..................................... 111
I.050 Exp dig in 1 cfg ................................... 112
I.051 Exp dig in 1 cfg ................................... 112
I.052 Exp dig in 1 cfg ................................... 112
I.053 Exp dig in 1 cfg ................................... 112
I.070 AND 1 cfg uscita ................................. 113
I.071 AND 2 cfg uscita ................................. 113
I.072 AND 3 cfg uscita ................................. 113
I.073 OR 1 cfg uscita ................................... 113
I.074 OR 2 cfg uscita ................................... 113
I.075 OR 3 cfg uscita ................................... 113
I.076 NOT 1 cfg uscita .................................. 113
I.077 NOT 2 cfg uscita .................................. 113
I.078 NOT 3 cfg uscita .................................. 113
I.079 NOT 4 cfg uscita .................................. 113
I.100 Dig output 1 cfg ................................... 113
I.101 Dig output 2 cfg ................................... 113
I.102 Dig output 3 cfg ................................... 113
I.103 Dig output 4 cfg ................................... 113
I.150 Exp DigOut 1 cfg ................................. 115
I.151 Exp DigOut 1 cfg ................................. 115
I.152 Exp DigOut 3 cfg ................................. 115
I.200 An In 1 Type ........................................ 117
INDEX PARAMETERS
ARTDriveG Instruction manual Index Parameters • 213
I.201 An In 1 offset ....................................... 117
I.202 An In 1 gain ......................................... 117
I.203 An In 1 minimum ................................. 118
I.204 An In 1 filter ......................................... 118
I.205 An In 1 DeadBand ................................ 118
I.210 An In 2 type ......................................... 117
I.211 An In 2 offset ....................................... 117
I.212 An In 2 gain ......................................... 117
I.213 An In 2 minimum ................................. 118
I.214 An In 2 filter ......................................... 118
I.215 An In 2 DeadBand ................................ 118
I.220 An In 3 type ......................................... 117
I.221 An In 3 offset ....................................... 117
I.222 An In 3 gain ......................................... 117
I.223 An In 3 minimum ................................. 118
I.224 An In 3 filter ......................................... 118
I.225 An In 3 DeadBand ................................ 118
I.300 Analog out 1 cfg .................................. 121
I.301 An out 1 offset .................................... 121
I.302 An out 1 gain ....................................... 121
I.303 An out 1 filter ...................................... 122
I.310 Analog out 2 cfg .................................. 121
I.311 An out 2 offset .................................... 121
I.312 An out 2 gain ....................................... 121
I.313 An out 1 filter ...................................... 122
I.350 Exp an out 1 cfg .................................. 123
I.351 Exp AnOut 1 offs ................................. 123
I.352 Exp AnOut 1 gain ................................. 123
I.353 Exp AnOut 1 filt .................................... 123
I.400 Inp by serial en .................................... 128
I.410 Exp in by ser en ................................... 128
I.420 Out by serial en ................................... 128
I.430 Exp OutBySer en .................................. 128
I.440 An in an da ser .................................... 128
I.450 An out by ser en .................................. 128
I.500 Encoder enable .................................... 129
I.501 Encoder ppr ......................................... 129
I.502 Enc channels cfg ................................. 129
I.503 Enc spd mul fact ................................. 129
I.504 Enc update time .................................. 129
I.505 Enc supply .......................................... 130
I.600 Serial link cfg ....................................... 130
I.601 Serial link bps ...................................... 131
I.602 Device address .................................... 131
I.603 Ser answer delay ................................. 131
I.604 Serial timeout ...................................... 131
I.605 En timeout alm .................................... 131
I.700 Option 1 type ....................................... 132
I.701 Option 2 type ....................................... 132
I.750 SBI Address ........................................ 133
I.751 CAN baudrate ...................................... 133
I.752 SBI Profibus Mode ............................... 133
I.753 SBI CAN Mode .................................... 133
I.754 Bus Flt Holdoff ..................................... 133
I.760 SBI to Drv W 0 .................................... 133
I.761 SBI to Drv W 1 .................................... 133
I.762 SBI to Drv W 2 .................................... 133
I.763 SBI to Drv W 3 .................................... 133
I.764 SBI to Drv W 4 .................................... 133
I.765 SBI to Drv W 5 .................................... 133
I.770 Drv to SBI W 0 .................................... 133
I.771 Drv to SBI W 1 .................................... 134
I.772 Drv to SBI W 2 .................................... 134
I.773 Drv to SBI W 3 .................................... 134
I.774 Drv to SBI W 4 .................................... 134
I.775 Drv to SBI W 5 .................................... 134
MENU P- PARAMETER
P.000 Cmd source sel ................................... 147
P.001 RUN input config ................................. 148
P.002 Reversal enable ................................... 149
P.003 Safety ................................................. 149
P.004 Stop mode .......................................... 149
P.005 Stop Key Mode .................................... 150
P.010 Control mode ...................................... 150
P.020 Mains voltage ...................................... 151
P.021 Mains frequency .................................. 151
P.040 Motor rated curr .................................. 151
P.041 Motor pole pairs .................................. 151
P.042 Motor power fact ................................. 152
P.043 Motor stator R ..................................... 152
P.044 Motor cooling ...................................... 152
P.045 Motor thermal K .................................. 152
P.060 V/f shape ............................................. 152
P.061 Max out voltage ................................... 153
P.062 Base frequency ................................... 153
P.063 V/f interm volt ...................................... 154
P.064 V/f interm freq ..................................... 154
P.080 Max output freq ................................... 154
P.081 Min output freq .................................... 154
P.100 Slip compensat ................................... 154
P.101 Slip comp filter .................................... 155
P.120 Manual boost [%] ................................ 155
P.121 Boost factor src ................................... 155
P.122 Auto boost en ...................................... 155
P.140 Magn curr gain .................................... 156
P.160 Osc damping gain ............................... 156
P.170 SpdPgainL .............................................. 157
P.171 SpdIgainL ............................................... 157
P.172 SpdPgainH ............................................. 157
P.173 SpdIgainH .............................................. 157
P.174 SpdGainThrL .......................................... 158
P.175 SpdGainThrH .......................................... 158
P.176 MaxSlipMotor ......................................... 158
P.177 MaxSlipRegen ........................................ 158
P.178 SpdPI lim FacSrc .................................... 158
P.180 SW clamp enable ................................ 158
P.200 En lim in ramp ..................................... 159
P.201 Curr lim in ramp .................................. 159
P.202 En lim in steady ................................... 159
P.203 Curr lim steady .................................... 159
P.204 Curr ctrl P-gain .................................... 159
P.205 Curr ctrl I-gain ..................................... 159
P.206 Curr ctr feedfwd .................................. 160
P.207 Curr lim in dec ..................................... 160
P.220 En DC link ctrl ...................................... 161
P.221 DC-lnk ctr Pgain .................................. 161
P.222 DC-lnk ctr Igain ................................... 161
P.223 DC-link ctr FF ...................................... 161
P.240 OverTorque mode ................................ 162
P.241 OT curr lim thr ..................................... 162
P.242 OT level fac src ................................... 162
P.243 OT signal delay .................................... 162
P.260 Motor OL prot en ................................. 163
P.280 BU Config ............................................ 163
P.281 Brake res value .................................... 163
P.282 Brake res power .................................. 163
P.283 Br res thermal K .................................. 163
P.300 DC braking level .................................. 164
P.301 DCB lev fac src .................................... 164
P.302 DC braking freq ................................... 164
P.303 DC braking start .................................. 164
P.304 DC braking stop ................................... 164
P.320 Autocapture mode ............................... 165
P.321 Autocapture Ilim .................................. 165
P.322 Demagnetiz time .................................. 165
P.323 Autocap f scan t .................................. 165
P.324 Autocap V scan t ................................. 165
P.325 Autocap spd src .................................. 165
P.340 Undervoltage thr .................................. 167
P.341 Max pwrloss time ................................ 168
P.342 UV alarm storage ................................. 168
P.343 UV Trip mode ...................................... 168
P.360 OV prevention ...................................... 171
P.380 Autoreset attmps ................................. 172
P.381 Autoreset clear .................................... 172
P.382 Autoreset delay ................................... 172
P.383 Autores flt rly ....................................... 173
P.400 Ext fault mod ....................................... 173
P.410 Ph Loss detec en ................................. 173
P.420 Volt reduc mode .................................. 174
P.421 V reduction fact ................................... 174
P.422 V fact mult src ..................................... 174
P.440 Frequency prog 1 ................................ 175
P.441 Freq prog 1 hyst .................................. 175
P.442 Frequency prog 2 ................................ 175
P.443 Freq prog 2 hyst .................................. 175
P.460 Const speed tol ................................... 177
P.461 Const speed dly ................................... 177
P.480 Heatsnk temp lev ................................. 177
P.481 Heatsnk temp hys ................................ 177
P.500 Switching freq ..................................... 178
P.501 Sw freq reduc en ................................. 178
P.502 Min switch freq ................................... 178
P.520 Overmod max lev ................................ 178
P.540 Out Vlt auto adj .................................... 178
P.560 Deadtime cmp lev ................................ 179
P.561 Deadtime cmp slp ............................... 179
P.580 Startup display .................................... 179
P.600 Speed dsply fact .................................. 179
P.999 Param prot code .................................. 180
MENU S - STARTUP
S.000 Mains voltage ...................................... 105
S.001 Mains frequency .................................. 105
S.100 Max out voltage ................................... 105
S.101 Base frequency ................................... 105
S.150 Motor rated curr .................................. 106
S.151 Motor pole pairs .................................. 106
S.152 Motor power factor .............................. 106
S.153 Motor stator R ..................................... 106
S.200 Cmd source sel ................................... 107
S.201 Max ref freq ......................................... 108
S.202 Ref 1 Channel ...................................... 108
S.203 Frequency ref 0 ................................... 108
S.300 Acc time 1 ........................................... 108
S.301 Dec time 1 .......................................... 108
S.400 Manual boost [%] ................................ 109
S.401 Auto boost en ..................................... 109
S.450 Slip compensat ................................... 109
S.451 Slip comp filter .................................... 110
S.900 Measure stator R ................................. 110
S.901 Save parameters ................................. 110
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1S9H27
Manuale AGy-EV34 -HGBVer. 0.1 - 26.4.2005
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